Unmanned aerial vehicle communication, monitoring, and traffic management

ABSTRACT

A computer-implemented method of communicating with an unmanned aerial vehicle includes transmitting a first message via a communications transmitter of a lighting assembly for receipt by an unmanned aerial vehicle. The first message includes an identifier associated with the lighting assembly, and the lighting assembly is located within a proximity of a roadway. The method also includes receiving a second message from the unmanned aerial vehicle via a communications receiver of the lighting assembly. The second message includes an identifier associated with the unmanned aerial vehicle. The method further includes transmitting a third message via the communications transmitter of the lighting assembly for receipt by the unmanned aerial vehicle. The third message includes an indication of an altitude at which the unmanned aerial vehicle should fly.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit of U.S. Provisional Application No.62/024,197, filed Jul. 14, 2014, the entire contents of which areincorporated in its entirety herein.

TECHNICAL FIELD

This document generally describes methods, systems and devices forcommunicating with unmanned aerial vehicles, monitoring unmanned aerialvehicles, and for managing air traffic for unmanned aerial vehicles.

BACKGROUND

Unmanned aerial vehicles, sometimes referred to as unmanned aircraft or“drones,” are aircraft that fly without a human pilot onboard theaircraft. In some cases, the unmanned aerial vehicle is controlled,operated or piloted in real time by a human via a ground-based controlsystem. In some cases, the unmanned aerial vehicle is supervised, but isnot piloted, in real time by a human operator via a ground-basedmonitoring system. In some cases, the unmanned aerial vehicle includesnavigational instrumentation and control circuitry that permit theunmanned aerial vehicle to navigate in real time without the aid of ahuman operator, so that the unmanned aerial vehicle is able toautonomously control its flight without the aid of a human operator inreal time.

Unmanned aerial vehicles have been used in military operations, such asmilitary surveillance, combat, and reconnaissance operations.Additionally, unmanned aerial vehicles have been proposed that woulddeliver books or other commercially ordered products to a customer'sresidence.

Public opinion has generally been supportive of the use of unmannedaerial vehicles for military surveillance, combat, and reconnaissanceoperations carried out internationally, but when it comes to domesticapplications—whether for military, civil, or commercial uses—publicopinion has been less enthusiastic. For example, privacy concerns havebeen raised regarding unauthorized or intrusive surveillanceopportunities that could arise as unmanned aerial vehicles become moreprevalent. Moreover, concerns have been raised related to the potentialfor injury or property damage that could be caused by unmanned aerialvehicles, or that operation of unmanned aerial vehicles proximate one'sprivate property or residence would be an unwelcome nuisance.

SUMMARY

In a first general aspect, a computer-implemented method ofcommunicating with an unmanned aerial vehicle includes transmitting afirst message via a communications transmitter of a lighting assemblyfor receipt by an unmanned aerial vehicle. The first message includes anidentifier associated with the lighting assembly, and the lightingassembly is located within a proximity of a roadway. The method alsoincludes receiving a second message from the unmanned aerial vehicle viaa communications receiver of the lighting assembly. The second messageincludes an identifier associated with the unmanned aerial vehicle. Themethod further includes transmitting a third message via thecommunications transmitter of the lighting assembly for receipt by theunmanned aerial vehicle. The third message includes an indication of analtitude at which the unmanned aerial vehicle should fly.

Various implementations may include one or more of the following. Theindication of the altitude at which the unmanned aerial vehicle shouldfly may include an identifier of an air corridor having associatedtherewith a predetermined minimum altitude and a predetermined maximumaltitude. The method may also include determining, via a computationunit of the lighting assembly, an altitude of the unmanned aerialvehicle, and the third message may include the altitude of the unmannedaerial vehicle. The identifier associated with the unmanned aerialvehicle may include a location indicator of the unmanned aerial vehicle,and determining the altitude of the unmanned aerial vehicle may be basedon the location indicator of the unmanned aerial vehicle and on alocation identifier of the lighting assembly. The identifier associatedwith the lighting assembly may include a location identifier of thelighting assembly. The location identifier of the lighting assembly mayinclude one or more GPS coordinates associated with the lightingassembly. The roadway may be associated with a right-of-way, and theidentifier associated with the lighting assembly may include a locationindicator associated with the right-of-way. The identifier associatedwith the unmanned aerial vehicle may include a location indicator of theunmanned aerial vehicle, and the method may further include determiningthat the unmanned aerial vehicle is outside of an airspace associatedwith the right-of-way, and the third message may include a warning thatthe unmanned aerial vehicle is outside of the airspace associated withthe right-of-way. The first message may include an indication of alanding area. The first message may include a location identifierassociated with an obstacle. The method may further include storing in amemory location of the lighting assembly the identifier associated withthe unmanned aerial vehicle and a time stamp. The method may furtherinclude transmitting a fourth message via the communications transmitterof the lighting assembly for receipt by a control center remote from thelighting assembly, where the fourth message includes the identifierassociated with the unmanned aerial vehicle and the time stamp. Themessage may further include transmitting, from a charging unit of thelighting assembly, a wireless charging signal for receipt by theunmanned aerial vehicle for charging a battery of the unmanned aerialvehicle. The method may further include transmitting a fourth messagevia the communications transmitter of the lighting assembly, the fourthmessage including the identifier associated with the unmanned aerialvehicle and a quantity associated with the wireless charging signal.Each of the first message, the second message, and the third message maybe encrypted for security. Each of the first message the second message,and the third message may include a security question. The identifierassociated with the unmanned aerial vehicle may include a locationindicator of the unmanned aerial vehicle, and the method may furtherinclude determining that the unmanned aerial vehicle is within apredetermined distance of a second unmanned aerial vehicle based on thelocation indicator of the unmanned aerial vehicle and on informationreceived from the second unmanned aerial vehicle, and the third messagemay include a warning that the unmanned aerial vehicle is within thepredetermined distance of the second unmanned aerial vehicle. The methodmay further include determining a navigational adjustment for theunmanned aerial vehicle, and the third message may include thenavigational adjustment for the unmanned aerial vehicle. The firstmessage may include an indication of weather, or may include anindication of a speed. The method may further include determining aspeed of the unmanned aerial vehicle. The speed of the unmanned aerialvehicle may exceed a predetermined speed threshold, and the method mayfurther include transmitting a fourth message that includes anindication of the speed of the unmanned aerial vehicle. The firstmessage may include an indication of a noise level, or may include anindication of an emissions level. The identifier associated with theunmanned aerial vehicle may include license or registration informationfor the unmanned aerial vehicle, and the method may further includedetermining whether the license or registration information for theunmanned aerial vehicle is valid. The method may further includedetermining that the unmanned aerial vehicle includes a weapon. Thefirst message may include an indication of an area that the unmannedaerial vehicle should avoid.

In a second general aspect, a lighting assembly includes a light polelocated within a proximity of a roadway, and a luminaire. The lightingassembly also includes a communications station associated with thelighting assembly. The communications station includes a communicationstransmitter configured to transmit a first message for receipt by anunmanned aerial vehicle, where the first message includes an identifierassociated with the lighting assembly. The communications station alsoincludes a communications receiver configured to receive a secondmessage from the unmanned aerial vehicle, where the second messageincludes an identifier associated with the unmanned aerial vehicle. Thecommunications station further includes a processing module configuredto determine an altitude at which the unmanned aerial vehicle shouldfly. The communications transmitter is further configured to transmit athird message for receipt by the unmanned aerial vehicle, where thethird message includes an indication of the altitude at which theunmanned aerial vehicle should fly.

Various implementations may include one or more of the following. Theindication of the altitude at which the unmanned aerial vehicle shouldfly may include an identifier of an air corridor having associatedtherewith a predetermined minimum altitude and a predetermined maximumaltitude. The processing module may further be configured to determinean altitude of the unmanned aerial vehicle, and the third message mayinclude the altitude of the unmanned aerial vehicle.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a conceptual diagram of an example unmanned aerial vehicleflight environment and an example system for communicating with unmannedaerial vehicles operating within the environment.

FIG. 2 is a conceptual diagram of example air corridors.

FIGS. 3A, 3B, and 3C are conceptual diagrams of example communicationstyles that an example communications station can use to communicatewith an example unmanned aerial vehicle.

FIG. 4 is a conceptual diagram that depicts an example unmanned aerialvehicle receiving a charging signal from an example communicationsstation.

FIG. 5 is a block diagram of an example communications station.

FIG. 6 is a flowchart of an example method that can be used tocommunicate with an unmanned aerial vehicle.

FIG. 7 is a block diagram of an example communications component.

FIG. 8 is a conceptual diagram of an example unmanned aerial vehicleflight environment and an example system for communicating with unmannedaerial vehicles operating within the environment.

FIG. 9 is a block diagram of an example unmanned aerial vehicle.

Like reference symbols in the various drawings indicate like elements.

DETAILED DESCRIPTION

Described herein are systems, devices and methods that can be used,according to some implementations, for one or more of providingcommunications with unmanned aerial vehicles, providing information to-and receiving information from unmanned aerial vehicles, aiding unmannedaerial vehicles, logging, chronicling or validating routes of unmannedaerial vehicles, managing aspects of unmanned aerial vehicle traffic,alleviating, reducing, or mitigating privacy concerns associated withunmanned aerial vehicles, checking or validating registration or licenseinformation for unmanned aerial vehicles, improving reliability ofunmanned aerial vehicle operations, sensing or monitoring for unmannedaerial vehicles, and improving public safety conditions associated withunmanned aerial vehicle operations. In general, the techniques, systemsand devices discussed herein may be used with any type of unmannedaerial vehicle, drone, unmanned aircraft, remotely piloted or remotelyoperated aircraft, or unmanned aircraft system, without limitation. Forsimplicity, the examples discussed herein will generically refer tounmanned aerial vehicles.

Unmanned aerial vehicles (“UAVs”) are aircraft that fly without a humanpilot onboard the aircraft, and have been used for many differentpurposes. While military-grade UAVs have long existed for carrying outmilitary operations or special operations applications, it is expectedthat general-purpose UAVs may become increasingly common in day-to-daylife. For example, UAVs may be used for various civil applications(e.g., police departments, fire departments, search and rescuedepartments, disaster response), recreational applications, commercialapplications, or other applications in the future. As one example of apotential future commercial use, some businesses have considered usingUAVs to perform delivery functions currently being performed byground-based delivery personnel who deliver goods via car, truck,bicycle, or by foot. Such deliveries may be from a retailer or warehouselocation to a consumer's residence, for example, or from a retailer orwarehouse to another business (related to a business-to-businesstransaction).

Unmanned aerial vehicles typically use aerodynamic forces to providelift and permit the aircraft to achieve flight. Some UAVs include one ormore fixed wings; some UAVs include one or more rotary blades or rotors;and some UAVs include both one or more fixed wings and one or morerotary blades or rotors. Some UAVs can takeoff and land without directhuman assistance, while others require some form of human assistance,for example to assist in lifting off or taking flight initially. SomeUAVs are gas (or other type of fuel) powered, while others are batterypowered. Some UAVs are powered by a combination of gas- or fuel powerand battery power.

UAVs can have many shapes, sizes, styles, and levels of complexity.Military-grade UAVs have tended to be large, complex and expensive, andhave been equipped to fly for long distances without refueling orrecharging. For example, some versions of the Predator drone are 27 ft.long with wingspans of nearly 50 ft., have a payload capacity of over1000 lbs., weigh over 2000 lbs. when loaded, have a flight range ofnearly 700 miles, and have a unit cost of about $4 million. It isexpected that many UAVs to be used for commercial or other purposes, bycontrast, will be much smaller, simpler, less expensive, and have a muchsmaller flight range. For example, some versions of an “octocopter” UAV,which includes eight small rotors, are about the size of sometraditional remote-controlled airplanes, are battery powered, have apayload capacity of about five pounds, and have a flight range of aboutten miles. Other delivery UAVs have been proposed that would have apayload capacity of up to 55 lbs., and a somewhat longer flight range.

Traditionally, UAVs have been controlled or piloted in real time by aground-based operator, who controls or partially controls the UAV usinga ground-based control system. Communications between the ground-basedcontrol system and the UAV can occur over one or more wireless datalinksor communication paths. In some cases, the communication signals caninclude one or more video channels or feeds. In some examples, satellitecommunications can be used, where communications from the ground-basedcontrol system to the UAV, and vice versa, pass though one or moreorbiting satellites. Alternatively, communications from the ground-basedcontrol system to the UAV, and vice versa, may pass over one or morenetworks or communication links, such as one or more cellular or otherphone-based networks, over remote control radio frequency links, UHF orL-band frequency links, microwave frequency links, or other appropriatedatalinks, networks, or communication paths.

Some UAVs are equipped with autopilot functionality to autonomouslycontrol their flight using one or more onboard computers and associatedsensors and other navigational instrumentation and control circuitry.Autonomously controlled UAVs typically receive positional updates viareceived Global Positioning System (“GPS”) signals. However, some typesof GPS and other satellite-based communications can be susceptible topoor weather conditions, can be restricted to areas that have aline-of-sight to an appropriate satellite, or can be susceptible tojamming, spoofing, or hacking attacks. In some examples, UAVs that flyautonomously send and/or receive information over one or more wirelessdatalinks, networks, or communication paths such as, for example, one ormore of the datalinks, networks or communication links discussed above.In some examples, combinations of the foregoing communications methodscan be used.

FIG. 1 is a conceptual diagram of an example unmanned aerial vehicleflight environment 100, and an example system for communicating withunmanned aerial vehicles operating within (or outside of) theenvironment 100. The environment 100 may represent, without limitation,a portion of a town, city, or metropolitan area, for example. Ingeneral, communications stations 101 (e.g., stations 101 a, 101 b, 101c, 101 d, 101 e, 101 f), which may be positioned on streetlights,traffic lights, utility poles, towers (e.g., cell towers),communications station poles, road signs or display monitors, buildings,trees, billboards, bridges, or other structures within a proximity of aroadway or a right-of-way, according to various implementations, can beused to communicate with UAVs. In various implementations, thecommunications stations 101 may also provide information to- and receiveinformation from UAVs, aid UAVs, log, chronicle or validate routes ofUAVs, manage aspects of UAV traffic, alleviate, reduce, or mitigateprivacy concerns associated with UAVs, check or validate registrationinformation for UAVs, sense or monitor for UAVs, improve reliability ofUAV operations, and improve public safety conditions associated with UAVoperations.

A roadway 102 is bounded by a first roadway edge 104 a and a secondroadway edge 104 b, and is associated with a right-of-way 106, which isdefined by a first right-of-way boundary 108 a and a second right-of-wayboundary 108 b. In some examples, the right-of-way 106 (and otherright-of-ways discussed later herein) may be a public right-of-way. Insome examples, the right-of-way 106 (and other right-of-ways discussedlater herein) may be a legal right-of-way. In the depicted example, theroadway 102 is located within the right-of-way 106, and is roughlycentered between the boundaries 108 a, 108 b of the right-of-way 106. Insome examples, the roadway 102 may have a width (e.g., distance betweenedges 104 a and 104 b) of about 24-32 feet for a two-lane roadway, andthe right-of-way 106 may have a width (e.g., distance between boundaries108 a and 108 b) of about 35-60 feet, for example. For simplicity,roadway 102 is depicted in FIG. 1 as a two-lane highway or road, but inother examples could have more (e.g., three, four, five, six, seven,eight, nine, ten, eleven, twelve, or more) or fewer (e.g. one or zero)lanes, and could be an interstate highway, a federal or state highway, acounty road, a city street, or the like. Roadway 102 may have anyappropriate width, and right-of-way 106 may similarly have anyappropriate width. In some examples, roadway 102 is contained withinright-of-way 106, but in some examples one or more portions of roadway102 may extend outside of right-of-way 106.

The first right-of-way boundary 108 a and the first roadway edge 104 adefine a first right-of-way zone 110 a therebetween, and the secondright-of-way boundary 108 b and the second roadway edge 104 b define asecond right-of-way zone 110 b therebetween. As one example, for thetwo-lane roadway 102, roadway 102 may have a width of about 32 ft., andright-of-way 106 may have a width of about 60 ft. Roadway 102 maygenerally be centered within the right-of-way 106, so that the firstright-of-way zone 110 a has a width of about 14 ft. and the secondright-of-way zone 110 b has a width of about 14 ft. As will be describedin more detail below, some implementations of the systems, devices andmethods discussed herein can facilitate UAV traffic in the airspace orairspaces above one or more of the first right-of-way zone 110 a and thesecond right-of-way zone 110 b (or above other right-of-ways orright-of-way zones).

The environment 100 also depicts a second roadway 112, bounded byroadway edges 114 a and 114 b, and a second right-of-way 116, defined byboundaries 118 a and 118 b. Right-of-way zones 119 a and 119 b aredefined between roadway edge 114 a and boundary 118 a, and betweenroadway edge 114 b and boundary 118 b, respectively. The environment 100similarly depicts a third roadway 120, bounded by roadway edges 122 aand 122 b, and a second right-of-way 124, defined by boundaries 126 aand 126 b. Right-of-way zones 128 a and 128 b are defined betweenroadway edge 122 a and boundary 126 a, and between roadway edge 122 band boundary 126 b, respectively. The third roadway 120 includes abridge 129.

Several cars or trucks 130 are shown driving on the roadways 102, 112,and 120, and several pedestrians 132 are depicted walking on a sidewalk134. In some examples, the pedestrians may be approaching or departingfrom a retail store 136 or an office building 138. A tree 140 and abillboard 142 are depicted, and in this example are located just outsideof the second right-of-way zone 110 b. Some of the branches and leaves144 of the tree 140 protrude into the airspace above right-of-way-zone110 b, as can be seen with reference to FIG. 1. Billboard 142 is locatednear the second right-of-way zone 110 b, in the depicted example.Another tree 143 is located in first right-of-way zone 110 a in thedepicted example.

A first lighting assembly 144 a is located within a proximity of aroadway (e.g., roadway 102 in the depicted example) or of a right-of-way(e.g., right-of-way 106 in the depicted example), or both. In thisexample, lighting assembly 144 a is a streetlight, and includes aluminaire 145 and a pole 146 (e.g., a light pole in this example). Acommunications station 101 a is associated with the lighting assembly144 a, and in the depicted example is attached to the lighting assembly144 a. For example, the communications station 101 a can be attached tothe light pole 146.

In various implementations, the communications station 101 a cancommunicate with a UAV 150 operating in the environment 100. In someexamples, a communications station 101 may communicate with UAVs 150 asthey fly in the environment 100, such as when the UAV 150 flies in avicinity or within communications range of the communications station101. In various implementations, the communications station 101 a maybroadcast a first message that includes an identifier associated withthe communications station 101 a, with the first lighting assembly 144a, or with both the communications station 101 a and the first lightingassembly 144 a. The UAV 150 may receive the first message from thecommunications station 101 a, and may transmit a second message thatincludes an identifier associated with the UAV 150, which may bereceived by the communications station 101 a. In variousimplementations, the communications station 101 a may transmit a thirdmessage, for receipt by the UAV 150, that includes an indication of analtitude at which the UAV 150 should fly, as will be discussed in moredetail below.

In some examples, a UAV 150 may communicate with a first communicationsstation when it is in a vicinity of the first communications station,and may communicate with a second communications station when it is in avicinity of the second communications station. For example, a secondlighting assembly 144 b is also located within a proximity of theroadway 102 (and the right-of-way 106 in this example), and acommunications station 101 b is associated with the lighting assembly144 b (attached to the lighting assembly 144 b in this example). As theUAV 150 flies in a direction 158, for example, the UAV 150 maycommunicate with communications station 101 a while in a vicinity of thecommunications station 101 a, and may communicate with communicationsstation 101 b while in a vicinity of the communications station 101 b.

In some examples, a handoff of the UAV 150, communications-wise, fromthe first communications station 101 a to the second communicationsstation 101 b can be executed. For example, as the UAV 150 flies indirection 158 away from the first communications station 101 a andtowards the second communications station 101 b, one or more ofcommunications station 101 a or 101 b may determine that communicationsstation 101 b should assume a larger communications role with the UAV150, and/or that communications station 101 a should assume a smallercommunications role with the UAV 150 (or both). In some examples, thisdetermination can occur at or about the time that the UAV 150 reaches alocation that is closer to the second communications station 101 b thanto the first communications station 101 a. In some examples, the UAV 150may communicate with both communications station 101 a andcommunications station 101 b. In some examples, one or more of thecommunications stations 101 a or 101 b may inform the UAV 150 which ofthe communications stations 101 a or 101 b may be considered a primarycommunications station for the UAV 150, for example at a given time. Insome examples, the UAV 150 may make a determination as to which of thecommunications stations 101 a or 101 b it will communicate with or willprimarily communicate with (e.g., based on signal strengths of receivedsignals from one or more of the stations, based on flight route andstation locations, based on current or expected UAV location, or otherfactors).

Third lighting assembly 144 c is located within a proximity of roadway112 and right-of-way 116, and a communications station 101 c isassociated with the lighting assembly 144 c (attached to the lightingassembly 144 c in this example), and fourth lighting assembly 144 d issimilarly located within a proximity of roadway 112 and right-of-way116, and a communications station 101 d is associated with the lightingassembly 144 d (attached to the lighting assembly 144 d in thisexample). Fifth lighting assembly 144 e is located within a proximity ofroadway 120 and right-of-way 124, and a communications station 101 e isassociated with the lighting assembly 144 e (attached to the lightingassembly 144 e in this example). A pole 147 is also located within aproximity of roadway 120 and right-of-way 124, and a communicationsstation 101 f is associated with the pole 147. In some examples, pole147 is a utility pole. In some examples, pole 147 is a communications orcommunications station pole.

As the UAV 150 proceeds along its flight path, it may communicate withcommunications stations (e.g., one or more of communications stations101 a, 101 b, 101 c, 101 d, 101 e, and 101 f) along the way. In someexamples, the particular communications station can initiatecommunications with the UAV 150. In some examples, the UAV 150 caninitiate communications with the particular communications station.

In various implementations, the communications stations 101 may providealtitude information to the UAV 150. For example, a communicationsstation 101 may provide an indication of altitude to the UAV 150. Invarious implementations, the indication of altitude may include analtitude that the UAV 150 is currently flying at. In some examples, thecommunications station 101 includes one or more sensors that thecommunications station 101 can use to determine an altitude that the UAV150 is flying at. In some examples, the communications station 101 candetermine the altitude based on information that is included in amessage received by the communications station 101 from the UAV 150. Forexample, the message received from the UAV 150 may include a locationidentifier (e.g., one or more GPS coordinates or one or morelatitude/longitude/elevation indications) that provides an indication ofan altitude of the UAV 150. In some examples, the communications station101 can determine the altitude based on a location indicator of theunmanned aerial vehicle and on a location identifier associated with thelighting assembly or communications station (e.g., one or more GPScoordinates or elevation or altitude indications for the lightingassembly or communications station).

In some examples, the indication of an altitude can include an altitudeor an altitude range that the UAV 150 should fly at, or an identifier ofan air corridor in which the UAV 150 should fly, as will be furtherdescribed below. In some implementations, the communications station 101may provide an indication of an altitude, an altitude range, or of oneor more air corridors that the UAV 150 should avoid flying at or in.

Other information that can be provided by the communications station 101to the UAV 150 can include indications of one or more obstacles that theUAV 150 may encounter during its flight, or that the UAV 150 shouldavoid during its flight. For example, the communications station 101 mayprovide the UAV 150 with an indication of the office building 138 or ofthe retail store 136, of the trees 140 or 143, or of the branches 144that protrude into the airspace of the right-of-way 110 b, of thebillboard 142, of the bridge 129, of utility poles or power lines,traffic lights, construction equipment (e.g., large cranes), mountainsor hills, or of other obstacles or impediments that the UAV 150 shouldavoid during its flight. In some examples, the indications of obstaclescan include a location identifier (e.g., one or more GPS coordinates orone or more latitude/longitude indications orlatitude/longitude/elevation indications) associated with thecorresponding obstacle.

In some examples, the communications station 101 can provide anindication of a landing area 156 (e.g., an emergency landing area orsafe landing area) where it may be safe for the UAV 150 to land shouldthe UAV 150 need to make an unscheduled landing. In some examples, theindication of the landing area can include a location identifier (e.g.,one or more GPS coordinates or one or more latitude/longitude orlatitude/longitude/elevation indications) associated with the landingarea 156. In some examples, the indication of the landing area caninclude directions to the landing area 156 based on a current locationor position of the UAV 150. In some implementations, landing area 156can include one or more charging stations, and a UAV 150 may use one ofthe charging stations to recharge one or more batteries of the UAV. Insome examples, landing area 156 or a portion of landing area 156 mayoverlap a portion of a right-of-way (e.g., right of way 106) or mayoverlap a portion of a right-of-way zone (e.g., zone 110 b).

In some examples, the communications station can provide an indicationof a package hub area 157, which may correspond to a package pick-up ordrop-off location or area, in various implementations. For example, inimplementations where the UAV 150 is used to deliver packages, thecommunications station 101 may provide an indication of a package hubarea 157 where one or more retailers may drop off merchandise orpackages to be delivered by a delivery service or company that utilizesUAVs to deliver the merchandise or packages. In various implementations,the indication provided by the communications station 101 can include alocation identifier (e.g., one or more GPS coordinates or one or morelatitude/longitude or latitude/longitude/elevation indications) for thepackage hub area 157. In some implementations, the indication caninclude directions to the package hub area 157 based on a currentlocation or position of the UAV 150. Package hub area 157 may includeone or more warehouses (not shown in FIG. 1). In some examples, a singleretailer may use the package hub area 157 to stage package delivery, andin some implementations, several retailers may use the package hub area157 to stage package delivery. In some implementations, package hub area157 can include one or more charging stations, and a UAV 150 may use oneof the charging stations to recharge one or more batteries of the UAV.In some examples, package hub area 157 or a portion of package hub area157 may overlap a portion of a right-of-way (e.g., right of way 106) ormay overlap a portion of a right-of-way zone (e.g., zone 110 b).

In some examples, the communications station 101 can provide anindication of weather to the UAV 150. For example, the communicationsstation 101 may provide a localized (e.g., in the area of thecommunications station 101 or the UAV 150) indication of wind speedand/or wind direction, which the UAV 150 may use in some implementationsto make navigational corrections. In some examples, the communicationsstation 101 may provide indications of severe weather warnings orconditions. In various implementations the communications station 101may be equipped with one or more sensors that can sense one or moreweather conditions, and the communications station 101 can convey theone or more sensed weather conditions to the UAV 150, as by a wirelessmessage, for example. In some examples, the communications station 101may receive a message (e.g., from a remote weather station or weatherservice) that includes weather-related information, and thecommunications station 101 may transmit a message to the UAV 150 thatincludes the weather-related information. Examples of weather relatedinformation that can be conveyed from the communications station 101 tothe UAV 150 can include, without limitation, wind speeds and winddirections, visibility levels, severe weather warnings, indications oflightning, indications of temperature, indications of humidity, orindications of hail, sleet, snow, or rain.

In some examples, the communications station 101 can provide the UAV 150with an indication of one or more areas to avoid, or one or more no-flyzones where the UAV 150 may not be permitted to fly. Referring again toFIG. 1, a no-fly zone 159 is depicted. In some examples, the no-fly zone159 may be a permanent no-fly zone, such as an area corresponding to anairport, a high security area (e.g., White House, Pentagon, militaryinstallation or base, or the like), or areas where UAVs may be unwelcome(e.g., near schools, near some businesses, near an athletic stadium,near an historic site). In some examples, the no-fly zone 159 maycorrespond to an area that is temporarily restricted due to a temporarycondition or situation. Examples of such temporary conditions orsituations can include, without limitation, natural disasters (e.g.,earthquakes, tornadoes, hurricanes, typhoons, floods) or otherweather-related conditions, emergencies (e.g., fires, accidents, policeor emergency response situations, and the like), congested areas (e.g.,congested due to UAV traffic, ground-based vehicle traffic, pedestriantraffic or gatherings, or the like), restricted areas, areas for which athreat has been identified or received, or areas associated with atemporary danger or cause for concern. In some cases, the communicationsstation 101 can inform the UAV 150 of an alternate route to bypass theno-fly zone 159 or the one or more areas to avoid. In some examples, ifa communications station 101 determines that a UAV 150 is flying in ano-fly zone 159, is flying within a predetermined distance of a no-flyzone 159, or appears to be on course towards a no-fly zone 159, thecommunications station 101 may transmit a warning message for receipt bythe UAV 150. In some examples, upon such a determination, thecommunications station may transmit a warning message for receipt by oneor more of a police or fire department, civil airspace authority,Federal Aviation Administration, a first responder, a securitydepartment, an owner of the UAV, or the like. In some examples, thecommunications station 101 may store an indication of the UAV 150 (e.g.,an identification or registration number) in a memory location of thecommunications station 101. In some examples, the communications station101 may issue a ticket or fine to a UAV that violates one or more of theno fly zone restrictions. In various implementations, the communicationsstation 101 may transmit a message that includes information regardingthe ticket or fine for receipt by one or more of the offending UAV, by acontrol center 148 remote from the communications station 101, by apolice department, or by an owner or operator of the UAV. In someexamples, the communications station 101 may store an indication of theticket or fine in a memory location of the communications station 101.

In some examples, no-fly zones may be imposed during recurring periodsof time, such as each day from 11:00 PM to 5:00 AM, or each day from9:00 PM to 6:00 AM, or each day from 6:00 PM to 7:00 AM. For example, acity or local government may determine that there should not be UAVtraffic during certain hours (e.g., hours during which a “UAV curfew”applies), and may impose a UAV no-fly zone over a large portion or allof the city during the appropriate times. Communications stations 101may communicate such no-fly zone information (e.g., one or more oflocations, times, and the like) to UAVs, according to someimplementations.

In some examples, the communications station 101 can provide anindication of speed to the UAV 150. For example, in someimplementations, the communications station 101 may determine a speedthat the UAV 150 is flying at (e.g., a velocity of the UAV), and mayprovide an indication of the determined speed to the UAV 150. In someexamples, the communications station 101 may include one or more sensorsthat can be used to determine a velocity of the UAV 150. In someexamples, the communications station 101 may determine a velocity of theUAV 150 based on information received from the UAV 150. For example, ifthe UAV 150 provides an indication of its location in first and secondmessages from the UAV 150 to the communications station 101, thecommunications station 101 may calculate a distance travelled by the UAV150 over a period of time (e.g., the time between messages), and maycalculate the velocity by dividing the distance travelled by the periodof time. In some examples, the time period between the two messages maybe determined based on when the messages were received by thecommunications station 101, and in some examples may be determined basedon information included with the messages, such as one or more timestamps.

In some examples, the communications station 101 may provide the UAV 150with an indication of a speed limit, or of multiple speed limits (e.g.,an upper limit and a lower limit), for an area proximate thecommunications station 101 or for an area that the UAV is flying in,flying towards, or destined for. The UAV may use this speed informationto make appropriate adjustments to comply with the provided information,for example. In some implementations, speed limits at which UAVs may flymay vary throughout the environment 100. For example, the firstcommunications station 101 a may communicate one or more first speedlimits when communicating with a UAV 150 based on prevailing speedlimits for an area associated with the first communications station 101a (or with the first lighting assembly 144 a), while the secondcommunications station 101 b may communicate one or more second speedlimits (which may differ from the first speed limits) when communicatingwith the UAV 150 based on prevailing speed limits for an area associatedwith the second communications station 101 b (or with the secondlighting assembly 144 b). In some examples, the communications station101 may issue a speeding ticket or fine to a UAV that violates one ormore of the speed limits or restrictions. In various implementations,the communications station 101 may transmit a message that includesinformation regarding the speeding ticket or fine for receipt by one ormore of the offending UAV, by a control center 148 remote from thecommunications station 101, by a police department, or by an owner oroperator of the UAV. In some examples, the communications station 101may store an indication of the ticket or fine in a memory location ofthe communications station 101.

In some examples, the communications station 101 can provide anindication of a noise level or sound level to the UAV 150. For example,the communications station 101 may provide an indication of a maximumpermissible noise or sound level associated with operation of the UAV.In some examples, the communications station 101 can provide anindication of an emissions level to the UAV 150. For example, thecommunications station 101 may provide an indication of a maximumpermissible emissions level associated with operation of the UAV (e.g.,for UAVs that are gas-powered or otherwise emit emissions). The UAV mayuse this noise or emissions information to make appropriate adjustmentsto comply with the provided information, for example. Similar to thespeed limits discussed above, noise levels or emissions levels may varyfor different areas, and different communications stations maycommunicate the levels associated with their particular area orlocation, for example. In some examples, the communications station 101may issue a noise ticket or fine or an emissions ticket or fine to a UAVthat violates one or more of the noise or emission limits orrestrictions. In various implementations, the communications station 101may transmit a message that includes information regarding the noiseticket or fine or the emissions ticket or fine for receipt by one ormore of the offending UAV, by a control center 148 remote from thecommunications station 101, by a police department, or by an owner oroperator of the UAV. In some examples, the communications station 101may store an indication of the ticket or fine in a memory location ofthe communications station 101.

In some examples, the communications station 101 (or group ofcommunications stations) can log, chronicle or validate a route of theUAV 150. For example, the communications station 101 may store, in amemory location of the communications station 101, one or more of anidentifier associated with the UAV 150, an indication that the UAV 150was in communication with the communications station 101, or anindication that the UAV 150 flew in a vicinity of the communicationsstation 101. In some examples, the communications station 101 may storeone or more time stamps or time indications along with one or more ofthe foregoing to establish the relevant time or times that the UAV 150was interacting with or in a vicinity of the communications station 101.As the UAV 150 flies its route, for example, each communications station101 (e.g., station 101 a, 101 b, 101 c, 101 d, 101 e, 101 f, or otherstations, depending on route) along the route may log, chronicle orrecord an indication that the UAV 150 was in communication, for example,with the communications station 101, and optionally the time or times atwhich the communications occurred. In this manner, an unbiased andverifiable record of UAV flight patterns or activity may be collectedand stored, which may validate that the UAV 150 flew its intended route,according to some implementations. Such records may be used to alleviateprivacy concerns, for example, and may permit companies that use UAVs toprovide proof that the UAVs operated as expected.

In some examples, a communications station 101 may transmit a messagefor receipt by a control center 148 remote from the lighting assembly144 or communications station 101, where the message includes theidentifier associated with the UAV, and optionally the time stamp. Thecontrol center 148 may aggregate such messages, which may be received bythe control center 148 from one or more communications stations 101(e.g., from all of the communications stations 101 within a city orwithin a portion of a city, region, neighborhood, or the like), forexample, and may use the received messages to map flight paths oractivities of the corresponding UAVs. Control center 148 is shown inenvironment 100, and in some examples a single control center 148 maycommunicate with all or substantially all of the communications stationswithin a city or region. In other examples, a city may include multiplecontrol centers 148. In some examples, the UAV 150 may store one or moreindications of its communications with one or more communicationsstations in a memory location on the UAV 150.

In some examples, one or more communications stations 101 may receive amessage with information concerning a UAV and an expected route of theUAV. In some examples, such messages may be received from UAVs, and insome examples such messages may be received from a control center 148,or from a business that operates UAVs. The message may indicate anidentifier for the UAV, and a time, time window, or time range duringwhich the UAV is expected to be in a vicinity of, and/or incommunication with, the communications station 101. The communicationsstation 101 may monitor this time, time window, or time range, and ifthe UAV fails to communicate with the communications station 101 at theidentified time or during the time window or time range, thecommunications station 101 may transmit one or more messages in responseto the failure to communicate. For example, the communications station101 may transmit a warning message to alert that the UAV has not been incontact with the communications station 101 at the expected time orduring the expected time window or range. In some examples, onecommunications station may communicate with one or more othercommunications stations and attempt to locate the unaccounted-for UAVbased on communications that may have been established between the oneor more other communications stations and the unaccounted-for UAV.

In some examples, a communications station 101 can determine whether aUAV 150 has a valid or current registration or license. For example, thecommunications station 101 can request a registration or licenseidentifier from the UAV 150, and can receive a message from the UAV 150that includes a registration or license identifier of the UAV 150. Invarious implementations, the communications station 101 may compare thereceived registration or license identifier from the UAV 150 with a listof valid (or in some examples, invalid) registration or licenseidentifiers, for example. In some examples, the communications station101 may store a list of registration or license identifiers in a memoryof the communications station 101, and may compare received registrationor license identifiers with identifiers on the stored list. In someexamples, the communications station 101 may determine validity orinvalidity of the registration identifier based on the identifier itselfor information or a designator or code within the identifier. In any ofthese or other manners, the communications station 101 may determinewhether the received registration or license identifier is valid orinvalid (e.g., expired), for example.

In some examples, the communications station 101, upon receiving theregistration or license identifier from the UAV 150, may communicatewith a control center 148 remote from the communications station 101, toauthenticate or validate the registration or license identifier of theUAV 150, or to determine that the registration or license identifier isinvalid. For example, the communications station 101 may transmit amessage for receipt by the control center 148 that includes the receivedregistration or license identifier from the UAV. The communicationsstation 101 may then receive from the control center 148 a message thatincludes an indication (e.g., valid or invalid) regarding theregistration or license identifier from the UAV 150. In some examples,the control center 148 may provide a list, and the communicationsstation 101 may compare the UAV registration or license identifier tothe list and make a determination regarding the UAV's compliance.

If the UAV 150 has an invalid registration or license, thecommunications station 101 may transmit a message to the UAV 150informing the UAV 150 that it has an invalid registration or license,for example. In some cases, the communications station 101 can transmita message for receipt by a communications device at police department(e.g., at a police station, police vehicle, or with a police officer) orcivil airspace authority (or other appropriate authority), to informthat the UAV has invalid registration or license. In some examples, thecommunications station may issue a “ticket” or fine due to the expiredor invalid registration or license. In various implementations, thecommunications station 101 may store an indication of the ticket or finein a memory location of the communications station, may transmit amessage for receipt by the UAV or by a police communications unit orcivil airspace authority, or may transmit a message for receipt by acontrol center 148 or by a command station associated with the UAV(e.g., at a command station for the company that operates the UAV). Suchtickets may also be issued by the communications station 101 forviolations of speed limits, emissions levels, noise levels, no-flyzones, or for other infractions discussed herein.

In some cases, the communications station 101 can determine that theregistration or license is currently valid, but that it will be expiringsoon, and in such cases can transmit a message for receipt by the UAV150 (or by a command station associated with the UAV) to inform the UAV150 that its registration or license will be expiring soon. Such amessage can include the date of expiration, for example.

Some implementations of the techniques, systems, and devices discussedherein can be used to promote, direct, or enforce UAV traffic managementfeatures, such as requiring, advising or providing information to assistUAVs to fly within particular airspaces. As one example, acommunications station 101 can require, advise or provide information toa UAV 150 to assist that the UAV 150 flies in one or more particular aircorridors, where in some examples an air corridor may refer to anairspace generally bounded laterally or horizontally (e.g., an airspacebounded to the left and to the right), and in some examples also boundedvertically (e.g., an airspace that includes a lower boundary, an upperboundary, or both lower and upper boundaries).

For example, a communications station 101 may provide a UAV 150 withinformation that instructs the UAV 150 to fly within one or more aircorridors located above one or more of the right-of-way zones (e.g.,zones 110 a, 110 b, 119 a, 119 b, 128 a, and 128 b) described above.Such air corridors may be bounded or defined, to the left or the right,by a boundary of a right-of-way or by an edge of a roadway (or by theairspace directly above the boundary or edge), for example, or in somecases may be bounded or defined by a predetermined lateral extensionapplied to a boundary of a right-of-way or an edge of a roadway (e.g., 2ft., 5 ft., 10 ft., 15 ft., 20 ft., or some other appropriate lateralextension).

In some examples, the communications station 101 may provide the UAV 150with location information associated with an air corridor, or with anairspace in which the UAV 150 should fly. For example, thecommunications station 101 may provide one or more GPS coordinates orother location indicators (e.g., latitude and longitude information, orlatitude/longitude/elevation information) associated with one or morecorridors (e.g., corresponding to a left or right boundary of thecorridor, or corresponding to an upper or lower boundary of thecorridor, or one or more combinations of the foregoing).

In some examples, the communications station 101 may provide the UAV 150with positional information regarding a position or location of the UAV150, or regarding a position or location of the UAV 150 with respect toan air corridor, to an air corridor boundary, to a right-of-wayboundary, or to an airspace in which the UAV 150 should fly. Forexample, the communications station 101 may determine a position orlocation of the UAV 150 (e.g., either based on one or more sensorreadings from one or more sensors of the communications station 101, orbased on information provided by the UAV 150 in a message, for example),and may determine that the UAV 150 is not flying where it should beflying (e.g., outside of a particular air corridor or airspace in whichthe UAV 150 should be flying).

In some examples, the communications station 101 can send a message tothe UAV 150 informing the UAV 150 that the UAV 150 is not flying in theparticular air corridor or airspace in which the UAV 150 should beflying. In some examples, the communications station 101 can send amessage to the UAV 150 that includes one or more positional or locationidentifiers, or one or more airspace identifiers, and the UAV 150 canuse this information to adjust its route so that the UAV 150 may fly ina proper air corridor or airspace. In some examples, the communicationsstation 101 can send a message to the UAV 150 that includes directionson how the UAV 150 should adjust its route so that the UAV may fly inthe proper air corridor or airspace. In some examples, thecommunications station may issue a “ticket” or fine when the UAV fliesoutside of a prescribed area or an area that the UAV should be flying in(e.g., if the UAV is flying at the wrong altitude, in an incorrectaltitude range, or in an incorrect air corridor). In variousimplementations, the communications station 101 may store an indicationof the ticket or fine in a memory location of the communicationsstation, may transmit a message for receipt by the UAV or by a policecommunications unit, civil airspace authority unit, or control center148, or may transmit a message for receipt by a command stationassociated with the UAV (e.g., at a command station for the company thatoperates the UAV). In some examples, a communications station may hold,detain or restrict a UAV from proceeding until it assumes a properaltitude (e.g., within a proper altitude range or air corridor). Forexample, the communications station may send a message to the UAV thatinforms the UAV that it may not proceed on its route until the UAVbegins to fly at a proper altitude, altitude range, or within a properair corridor. If and when the UAV complies, the communications stationmay release its hold on the UAV (e.g., by sending a message to the UAVthat informs the UAV it may proceed), and the UAV may proceed on itsroute.

Referring again to FIG. 1, the UAV 150 is located in an airspaceassociated with the right-of-way 106. In particular, the UAV 150 isflying in an airspace bounded laterally by the right-of-way boundaries108 a and 108 b (e.g., by a vertical extension of the boundaries 108 aand 108 b). In the depicted example, the UAV 150 is additionally locatedin an airspace associated with the right-of-way zone 110 a, and isflying in an airspace bounded laterally by the right-of-way boundary 108a and the roadway edge 104 a (e.g., bounded by vertical extensions 152and 154, respectively, of the boundary 108 a and the roadway edge 104a).

The air corridors may further be bounded or defined, from above andbelow, by appropriate altitude levels, such as a predetermined minimumaltitude level and a predetermined maximum altitude level. Example upperand lower altitude boundaries for the air corridors might be, forexample: a first corridor with lower altitude boundary of 100 ft. andupper altitude boundary of 150 ft.; a second corridor with loweraltitude boundary of 150 ft. and upper altitude boundary of 200 ft.; athird corridor with lower altitude boundary of 200 ft. and upperaltitude boundary of 250 ft.; a fourth corridor with lower altitudeboundary of 250 ft. and upper altitude boundary of 300 ft.; a fifthcorridor with lower altitude boundary of 300 ft. and upper altitudeboundary of 350 ft.; and a sixth corridor with lower altitude boundaryof 350 ft. and upper altitude boundary of 400 ft., where each of thefirst through sixth corridors are bounded on the left by an airspaceabove right-of-way boundary 108 a and on the right by an airspace aboveroadway edge 104 a (or alternatively by an airspace above right-of-wayboundary 108 b).

In some examples, a single air corridor may be defined above aright-of-way zone (e.g., above zone 110 a, 110 b, 119 a, 119 b, 128 a,or 128 b), for example having upper and lower boundary 400 ft. and 100ft., respectively. In some examples, one or more of the air corridors(e.g., the first, second and third corridors) may be reserved for UAVtraffic in a first direction, and one or more of the air corridors(e.g., the fourth, fifth, and sixth corridors) may be reserved for UAVtraffic in a second direction (e.g., a direction opposite of the firstdirection). As another example, the first, third and fifth corridors maybe reserved for UAV traffic in a first direction, and the second,fourth, and sixth corridors may be reserved for UAV traffic in a seconddirection (e.g., a direction opposite of the first direction).

In some examples, the communications stations 101 may direct traffic orprovide traffic management information such that all or substantiallyall UAV traffic in an airspace above a right-of-way zone travels in thesame direction. In some examples, the communications stations 101 maydirect traffic or provide traffic management information such that allor substantially all UAV traffic in an airspace associated with aright-of-way zone flows in a direction consistent with vehicular trafficnear the right-of-way zone. Referring again to FIG. 1, for example, thecommunications stations 101 may direct traffic or provide trafficmanagement information such that UAV traffic in a first direction 161 isconfined to the airspace above right-of-way zone 110 b, and that UAVtraffic in a second (opposite) direction 162 is confined to the airspaceabove right-of-way zone 110 a, where such UAV traffic in the directions161 and 162 is consistent with the vehicular traffic in the trafficlanes of roadway 102 nearest the respective right-of-way zones 110 a and110 b.

As described above, a given communications station 101 may be incommunication with several UAVs 150 at a given time or during a givenwindow of time. For example, the communications station 101 a maymaintain contact or communications with each of the UAVs 150 within aproximity of the communications station 101 a, within a predetermineddistance from the communications station 101 a, within communicationsrange of the communications station 101 a, or for which thecommunications station 101 a is the station nearest the UAV's locationat a given time, according to various implementations. As such, in someimplementations the communications station 101 a may maintain or havevisibility to the location or position of each of the UAVs 150 that thecommunications station 101 a is in contact or in communication with at agiven time or during a given window of time.

In some examples, the communications station 101 a may determine that afirst UAV is too close to a second UAV (e.g., within a predetermineddistance of the second UAV, or vice versa), and may send a warningmessage to one or both of the first UAV and the second UAV. In someexamples, the communications station 101 a may determine one or morenavigational adjustments for one or both of the first UAV and the secondUAV, and may communicate the one or more navigational adjustments to thefirst UAV or the second UAV, or may communicate a first navigationaladjustment to the first UAV and a second navigational adjustment to thesecond UAV. The first UAV, second UAV, or both UAVs may use the one ormore navigational adjustments to alter a position or route, for example,to maintain a safe distance between the UAVs and/or avoid a collisionbetween the UAVs. This may reduce collisions between UAVs and improvesafety relating to UAV operating conditions, according to someimplementations.

FIG. 2 is a conceptual diagram of example air corridors. Shown in FIG. 2is the roadway 102 and right-of-way that includes right-of-way zones 110a and 110 b of FIG. 1. Also shown from FIG. 1 are the verticalextensions 152 and 154, respectively, of the right-of-way boundary 108 aand the roadway edge 104 a. A first air corridor 170, located aboveright-of-way zone 110 a in this example, is defined to have an examplelower boundary altitude (e.g., a predetermined minimum altitude) of 100ft. above ground and an example upper boundary altitude (e.g., apredetermined maximum altitude) of 175 ft. above ground; a second aircorridor 172 is located directly above the first air corridor 170, andis defined to have an example lower boundary altitude of 175 ft. aboveground and an example upper boundary altitude of 250 ft. above ground; athird air corridor 174 is located directly above the second air corridor172, and is defined to have an example lower boundary altitude of 250ft. above ground and an example upper boundary altitude of 325 ft. aboveground; and a fourth air corridor 176 is located directly above thethird air corridor 174, and is defined to have an example lower boundaryaltitude of 325 ft. above ground and an example upper boundary altitudeof 400 ft. above ground. For simplicity, air corridors are depicted onlyabove right-of-way zone 110 a in FIG. 2, but similar air corridors mayalso be defined above right-of-way zone 110 b, for example. The altitudeboundary levels discussed herein are intended to be illustrative, andany appropriate altitude boundaries can be used for the air corridors.Also, while air corridors are described herein as located aboveright-of-way zones, it will be understood that the air corridorsdescribed herein may exist across the entire width of right-of-ways,above roadways, above combinations of the foregoing, above areas outsideof right-of-ways, above areas adjacent to right-of-ways (e.g., areasoutside of or included in a lateral extension of a right-of-way), aboveareas detached from a right-of-way, or above any appropriate area.

In some examples, the communications station 101 may transmit a messagefor receipt by the UAV 150 that includes an altitude at which the UAV150 should fly. For example, the message may instruct the UAV 150 as toa particular air corridor in which that the UAV 150 should fly. In someexamples, the message may instruct the UAV 150 to fly within an altituderange, for example within the altitude range of 200-300 feet aboveground. In various implementations, the information included in themessage from the communications station 101 includes an indicator of aright-of-way or of a right-of-way zone. In some examples, theinformation included in the message from the communications station 101includes an indicator of a direction of travel.

The communications station 101 may make a determination regarding anappropriate air corridor or indicator of right-of-way or right-of-wayzone, direction of travel, or altitude range based on local UAV trafficlevels in some implementations, or based on one or more other factorsincluding predetermined UAV flight patterns, weather conditions, thestyle or type of UAV, and others. In some examples, the communicationsstation 101 may coordinate UAV traffic in an area proximate thecommunications station 101, for example in a manner analogous to how anair traffic controller coordinates aircraft traffic in a vicinity of anairport. In some examples, for each UAV that enters an area proximatethe communications station 101 or for which the communications station101 is responsible, the communications station 101 provides informationregarding where the UAV should fly, for example.

By facilitating UAV traffic in airspace above right-of-way zones, insome implementations, safe and predictable operating conditions may bepromoted. For example, UAVs generally restricted to flying aboveright-of-way zones may cause less damage if they lose control and crashwithin the right-of-way zones, as opposed to crashing on a roadway or inan area frequented by pedestrians, for example. Also, by facilitatingUAV traffic according to particular air corridors, UAV trafficcongestion may be better managed and potential for UAV collisions may bereduced or minimized, for example.

By facilitating or confining UAV traffic to or substantially toairspaces above right-of-ways or right-of-way zones for all or for aportion of a UAV's flight route, privacy concerns relating to UAVs maybe reduced or alleviated, according to some implementations. Forexample, by restricting UAVs to generally fly in airspaces above suchright-of-ways or above such right-of-way zones, the public may be lessconcerned about privacy invasion, intrusive surveillance, or potentialfor nuisance that might be caused by UAVs flying unregulated or withoutrestriction regarding where the UAV may fly in relation to privateresidences or private property. It will be understood that, in general,for UAV flight routes, such as for UAVs making deliveries of packages toprivate residences or to businesses, or picking up or dropping offpackages from package hub areas 157, or for other reasons, that the UAVsmay have to fly above areas not associated with right-of-ways during aportion of the UAVs flight route.

In some examples, a communications station can operate as a UAV tollstation. For example, a communications station can assess a toll on UAVsthat fly within a particular airspace, such as within a particular aircorridor. In various implementations, the communications station maystore an indication of an identifier associated with the UAV, anoptionally an indication of the toll, in a memory location of thecommunications station. In various implementations, the communicationsstation may transmit a message that includes information regarding thetoll for receipt by one or more of the UAV, by the control center 148remote from the communications station, or by an owner or operator ofthe UAV.

In some examples, one or more of the air corridors may be an “express”corridor. For example, an owner or operator of a UAV may purchase alicense or pass that may permit the UAV to fly in the designated expresscorridor, and the communications station may limit access to the expresscorridor to only those UAVs that have the license or pass to operate inthe express corridor. If the communications stations determines that aUAV is flying in an express corridor without a license or pass thatentitles the UAV to fly in the express corridor, the communicationsstation may issue a ticket or fine in a manner similar to thosediscussed herein with reference other types of tickets or fines.

FIG. 8 is a conceptual diagram of an example unmanned aerial vehicleflight environment 400 and an example system for communicating withunmanned aerial vehicles operating within the environment. Theenvironment 400 may represent, without limitation, a portion of a town,city, or metropolitan area, for example. The environment 400 includes aseries of streets or roadways, where the streets or roadways maygenerally be located within rights-of-ways (e.g., within publicrights-of-ways or legal-rights-of-ways, or both). For simplicity,roadways, right-of-ways, and one or more right-of-way zones associatedwith the roadway and/or the right-of-way are depicted as a single linein FIG. 8. North/south roadways/right-of-ways are depicted andrepresented by numerals 402, 404, 405, 406, 408, 410, and 412.Similarly, east/west roadways/right-of-ways are depicted and representedby numerals 414, 416, 418, 420, 422, 424, and 426. A warehouse 428 islocated near the intersection of roadways/right-of-ways 402 and 414, andmay represent a retail delivery departure location, for example, whereUAVs may depart from warehouse 428 to deliver packages. Warehouse 428may alternatively represent a delivery service provider, or a packagehub area 157 (see FIG. 1). Twelve example communications stations: A430, B 432, C 434, D 436, E 438, F 440, G 442, H 444, I 446, J 448, K450, and L 452 are depicted in the environment 400. In variousimplementations, one or more of the communications stations 430-452 maybe associated with a lighting assembly, such as a streetlight, a trafficlight, a parking lot light, a message board, or the like, and may beattached to the lighting assembly in some examples. One or more of thecommunications stations 430-452 may be associated with a building, abillboard, a tree, a bridge, a tower, a utility pole, a communicationspole, a road sign, or other structures. In some examples, thecommunications stations 430-452 may correspond to any of thecommunications stations (e.g., communications stations 101 a-f, 202,222, 252) discussed herein. Several residences 454, 456, 458, 460, 462,464, 466, 468, 470, 472, 474, 476 (e.g., houses, apartments, townhouses,condominiums, or the like) are depicted in the environment 400.

In some examples, a UAV can follow a flight route 478 to deliver apackage from the warehouse 428 to the residence 464. In general, route478 begins at or near warehouse 428, crosses roadway/right-of-way 414,proceeds east until near the intersection of roadway/right-of-way 404and roadway/right-of-way 414, turns south along roadway/right-of-way 404and continues to near the intersection of roadway/right-of-way 404 androadway/right-of-way 424, turns east along roadway/right-of-way 424,until arriving at residence 464 (e.g., crossing overroadway/right-of-way 424), where it may deliver the package.

As described above, the UAV may generally fly within airspacesassociated with one or more of right-of-ways, right-of-way zones,roadways, or with any of the foregoing including lateral extensions tothe right-of-ways, right-of-way zones, or roadways. In general,communications stations 430-452 may provide to the UAV any of theinformation described above herein with reference to FIGS. 1 and 2. Thecommunications stations 430-452 may also collect information from theUAV as described herein. The communications stations 430-452 may provideinformation that instructs the UAV to fly in a particular airspace orair corridor, for example. The communications stations 430-452 may alsolog, chronicle, or record the route 478 of the UAV, or may record anindication of communications with the UAV or of the UAV's presence in avicinity of the respective communications station, including anindication of the time or times that such communications occurred.

In some examples, communications station A 430 may establishcommunications with the UAV before the UAV departs from the warehouse428, and may initially be the primary communications station for the UAVbased on its proximity to the UAV's departure point as the UAV travelsalong its route 478. In some examples, communications station A 430 mayremain the primary communications station for the UAV until the UAVreaches a location at or near the intersection of roadway/right-of-way404 and roadway/right-of-way 416, where communications station D 436 maytake over for communications station A 430 as the primary communicationsstation for the UAV. In some examples, communications station D 436 mayremain the primary communications station for the UAV until the UAVreaches a location at or near the intersection of roadway/right-of-way404 and roadway/right-of-way 420, where communications station G 442 maytake over for communications station D 436 as the primary communicationsstation for the UAV.

In some examples, communications station G 442 may remain the primarycommunications station for the UAV until the UAV reaches a location ator near the intersection of roadway/right-of-way 404 androadway/right-of-way 424, where communications station J 448 may takeover for communications station G 442 as the primary communicationsstation for the UAV. Alternatively, in some examples communicationsstation G 442 may remain the primary communications station for the UAVuntil the UAV reaches a location at or near the intersection ofroadway/right-of-way 405 and roadway/right-of-way 424, wherecommunications station K 450 may take over for communications station G442 as the primary communications station for the UAV. In some examples,communications station K 450 may remain the primary communicationsstation for the UAV until the UAV reaches a location at or near theintersection of roadway/right-of-way 408 and roadway/right-of-way 424,where communications station L 452 may take over for communicationsstation K 450 as the primary communications station for the UAV. In someexamples, communications station L 452 may remain the primarycommunications station for the UAV while the UAV delivers its package toresidence 464.

After making the delivery to residence 464, the UAV may return to thewarehouse 428. In some examples, the UAV may return in the oppositedirection along route 478, for example, and may generally communicatewith the communications stations described above with reference to route478. In some examples, the UAV follows a similar route to route 478, butflies on the opposite sides of the roadway/right-of-ways as compared tothe above-described and depicted route 478 in FIG. 8, so as to be flyingin generally the same direction as the nearest ground-based trafficlane. So, for example, on its return flight from residence 464 towarehouse 428, the UAV may fly along the north side ofroadway/right-of-way 424, along the east side of roadway/right-of-way404, and along the north side of roadway/right-of-way 414, whilegenerally still following route 478, for example.

In some examples, one or more residences may be associated with anaggregate delivery area 480 (labeled “A” in FIG. 8). For example, tofacilitate easier UAV delivery of packages, the residences 466, 468,470, 472, 474, and 476 may be associated with aggregate delivery area480, which may correspond to a location that a UAV may deliver packagesfor any of the corresponding residences 466-476. Residences 466-476 maycorrespond to residences on a particular block or in a particularneighborhood, for example, or within a particular housing development orassociation, according to various implementations, or according to anyother appropriate grouping.

In some examples, a UAV can follow a flight route 482 to deliver apackage from the warehouse 428 to the aggregate delivery area 480. Ingeneral, route 482 begins at or near warehouse 428, crossesroadway/right-of-way 414, proceeds east until near the intersection ofroadway/right-of-way 410 and roadway/right-of-way 414, turns south alongroadway/right-of-way 410 and continues to near the intersection ofroadway/right-of-way 410 and roadway/right-of-way 426, turns east alongroadway/right-of-way 426, until arriving at aggregate delivery area 480(e.g., crossing over roadway/right-of-way 426).

In some examples, communications station A 430 may establishcommunications with the UAV before the UAV departs from the warehouse428, and may initially be the primary communications station for the UAVbased on its proximity to the UAVs departure point. In some examples,communications station A 430 may remain the primary communicationsstation for the UAV until the UAV reaches a location at or near theintersection of roadway/right-of-way 405 and roadway/right-of-way 414,where communications station B 432 may take over for communicationsstation A 430 as the primary communications station for the UAV. In someexamples, communications station B 432 may remain the primarycommunications station for the UAV until the UAV reaches a location ator near the intersection of roadway/right-of-way 408 androadway/right-of-way 414, where communications station C 434 may takeover for communications station B 432 as the primary communicationsstation for the UAV. In some examples, communications station C 434 mayremain the primary communications station for the UAV until the UAVreaches a location at or near the intersection of roadway/right-of-way410 and roadway/right-of-way 416, where communications station F 440 maytake over for communications station C 434 as the primary communicationsstation for the UAV. In some examples, communications station F 440 mayremain the primary communications station for the UAV until the UAVreaches a location at or near the intersection of roadway/right-of-way410 and roadway/right-of-way 420, where communications station I 446 maytake over for communications station F 440 as the primary communicationsstation for the UAV. In some examples, communications station I 446 mayremain the primary communications station for the UAV until the UAVreaches a location at or near the intersection of roadway/right-of-way410 and roadway/right-of-way 424, where communications station L 452 maytake over for communications station I 446 as the primary communicationsstation for the UAV. In some examples, communications station L 452 mayremain the primary communications station for the UAV while the UAVdelivers its package to aggregate delivery area 480.

In various implementations, one or more of the communications stations430-452 may communicate with one another (e.g., share information), andmay communicate UAV traffic information, such as general UAV traffic orcongestion levels, UAV traffic or congestion levels associated with aparticular air corridor or group of air corridors, UAV traffic orcongestion levels associated with a particular right-of-way orright-of-way zone, or UAV traffic or congestion levels associated with aparticular area of the environment 400 (e.g., a particular neighborhood,an area in the vicinity of an event, situation, structure, or the like)for example. In some examples, a communications station may use thistraffic information to determine an appropriate route or routeadjustment for a UAV. For example, if UAV traffic is particularly heavyalong one or more portions of route 478, communications station A 430(or another communications station) may instead suggest that the UAV flysouth along roadway/right-of-way 405, 406, 408, 410, or 412, rather thanalong roadway/route 404 (as depicted in route 478), for example. Thecommunications station A 430 may communicate this route or routeadjustment, or another appropriate route adjustment, to the UAV, forexample.

With reference again to FIG. 1, in some examples, a UAV 150 can requestpermission from a communications station 101 to fly outside of adesignated area (e.g., outside of a prescribed airspace above aright-of-way or outside of a prescribed airspace above a right-of-wayzone). For example, the UAV 150 may be delivering a package to apersonal residence, and may need to fly outside of a prescribed airspaceto make the delivery. For example, in delivering the package toresidence 464 (see FIG. 8), the UAV may temporarily need to fly outsideof a right-of-way airspace. In some examples, the communications station101 may receive the request, and may grant permission for the UAV to flyoutside of the prescribed airspace. In some cases, the communicationsstation 101 may monitor the UAV to ensure that the UAV returns to theprescribed airspace within a predetermined period of time, for example.In some examples, the UAV 150 may not request permission from thecommunications station 101 to fly outside of a designated area.

In some examples, the techniques, systems, and devices discussed hereincan instruct, advise, or inform a UAV regarding flying in an airspaceabove a right-of-way, such as directly above right-of-way 106, 116, or124, or within a predetermined distance outside of a space directlyabove right-of-way 106, 116, or 124. In some examples, the techniques,systems, and devices discussed herein can instruct, advise, or inform aUAV regarding flying in an airspace above one of the right-of-way zones110 a, 110 b, 119 a, 119 b, 128 a or 128 b. For example, in an airspacedirectly above one of the right-of-way zones 110 a, 110 b, 119 a, 119 b,128 a or 128 b, or within a predetermined distance outside of a spacedirectly above one of the right-of-way zones 110 a, 110 b, 119 a, 119 b,128 a or 128 b, such as a lateral extension to the zone.

FIGS. 3A, 3B, and 3C are conceptual diagrams of example communicationstyles that an example communications station can use to communicatewith an example UAV. In FIG. 3A, a communications station 202,associated with a lighting assembly 203 a in this example, iscommunicating with a UAV 204 via a direct wireless communication link206. Examples of direct communication link 206 can include, withoutlimitation, a Bluetooth communication link, a near field communication(“NFC”) link, a machine-to-machine (“M2M”) communication link, acellular link, an IEEE802-style (e.g., using any of the variousIEEE802-based protocols) communication link, an infrared communicationlink, an ISM band communication link, a radio frequency identification(“RFID”) communication link, or other appropriate direct wirelesscommunication link.

In FIG. 3B, the communications station 202, associated with a lightingassembly 203 b in this example, is communicating with the UAV 204 via asatellite communication link 208, where communications between thecommunications station 202 and the UAV 204 pass through a satellite 210.

In FIG. 3C, the communications station 202, associated with lightingassembly 203 c in this example, is communicating with the UAV 204 via anetworked communication link 212, where communications between thecommunications station 202 and the UAV 204 pass through one or morenetworks 214 (illustrated by a “cloud” in FIG. 3C). Examples of networks214 can include one or more cellular or other phone-based networks, theInternet, the “cloud” or one or more networks providing access to theInternet or the cloud, one or more mesh networks, a local or wide-areanetwork, a microwave network, a radio frequency network, or otherappropriate datalinks or networks as will be known to one of ordinaryskill in the art. In various examples, the one or more networks 214 mayinclude a public network and/or a private network.

In FIGS. 3A-3C, the communications station 202 is depicted near the topof the light pole of the lighting assembly. One advantage to locatingthe communications stations on lighting assemblies is that the lightingassemblies already are wired for power, for example, and locating thecommunications station near the top of the light pole may dissuadevandals from attempting to tamper with, gain access to, damage, ormisappropriate the communications station 202, according to someimplementations. In other examples, the communications station 202 couldbe located at other locations on the light pole or on the lightingassembly, such as nearer the luminaire as depicted in FIG. 3C. As can beseen in FIG. 3C, the communications station 202 is located on agenerally horizontal (in some examples) or arched (in some examples)portion of the lighting assembly 203 c.

The lighting assembly 203 a is similar to the lighting assemblies 144depicted in FIG. 1. FIGS. 3B and 3C show alternative lighting assemblies203 b and 203 c, respectively, and in general the communicationsstations discussed herein may be associated with any type of lightingassembly (e.g., streetlight, parking lot light, traffic light, displaymonitor). Assembly 203 b includes a luminaire 216 b that is generallylocated above the light pole of the assembly 203 b. Assembly 203 cincludes a luminaire 216 c generally shaped like a panel, for example.As described previously, the communications stations can also oralternatively be located on traffic lights, utility poles,communications station poles, towers (e.g., cell towers), road signs ordisplay monitors, buildings, trees, billboards, bridges, or otherstructures within a proximity of a roadway or a right-of-way, accordingto various implementations. In some examples, the communications stationmay not be located within a proximity of a roadway or a right-of-way.

In some examples, a mobile communications station may be used. Forexample, a vehicle (e.g., car, truck, van, or the like) may be equippedwith a communications station as described herein or with thefunctionality of a communications station as described herein. Invarious implementations, the mobile communications station may be usedto provide mechanical, electrical, or information technology support toa UAV, for example. In some examples, the mobile communications stationmay be used to respond to UAVs that land in a safe landing area (e.g.,landing area 156, see FIG. 1). In some examples, the mobilecommunications station may provide charging services to a UAV that haslanded, so that the UAV may recharge its batteries, for example. In someexamples, the mobile communications station can retrieve UAVs that maybe inoperable or otherwise unable to fly to their intended destinationor return to their base. In various implementations, the mobilecommunications station may be in communications with one or more of thecommunications stations described herein (e.g., any of thecommunications stations 101 a, 101 b, 101 c, 101 d, 101 e, 101 f, 202 orother communications stations described herein).

FIG. 4 is a conceptual diagram 220 that depicts an example UAV 221receiving a charging signal from an example communications station 222.As can be seen in FIG. 4, the UAV 221 is hovering relatively close tothe communications station 222. A charging unit 223 of thecommunications station 222 may transmit a charging signal 224 forreceipt by a charging module 226 of the UAV 221, and the charging module226 of the UAV 221 may use energy received via the charging signal 224to charge one or more batteries 228 of the UAV 221. In this manner, theUAV 221 may wirelessly charge one or more batteries 228 of the UAV 221without returning to a base, for example. UAV 221 may wirelessly chargeone or more batteries 228 of the UAV 228 without landing (e.g., whileremaining airborne), for example. In various implementations, near fieldcharging (“NFC”) technologies or other appropriate charging technologiescan be used.

In some examples, the UAV 221 can hover relatively near thecommunications station 222, and can drop or lower a communications orcharge cord (not shown), that can make contact with a portion of thecommunications station 222, and the charging unit 223 can send a chargesignal via the charge cord to provide wired charging for the UAV 221. Insome examples, the UAV 221 can drop a cable or cord that may or may notmake physical contact with the communications station 222, but may be inclose proximity to the communications station 222, and may be used toprovide ultra short range communications (e.g., messagingcommunications, wireless charging capability, etc.), which may permitthe UAV 221 to hover at a distance (e.g., several feet, yards, or metersfrom the communications station) yet permit the cable, cord or a portionof the cable or cord to get much closer to the communications station222 (e.g., within a couple of feet, within one foot, within a fewinches, within an inch, or physically touching or contacting), to betterfacilitate wireless or contact-based charging, in some implementations.In some examples, a releasable magnetic contact may be used tofacilitate contact between a portion of the cable or cord and thecommunications station 222, for example.

The communications station 222 is attached to an example lightingassembly 225 that includes a luminaire 229. Dashed outline 227 shows anexample of an alternative location on lighting assembly 225 wherecommunications station 222 could be located in some implementations (orat any other appropriate location on the lighting assembly 225).

In some examples, the communications station 222 tracks a quantityassociated with the charging signal 224, such as an amount of energyprovided by the communications station 222 to the UAV 221, and a billingmodule 230 of the communications station 222 can cause a message to betransmitted that includes an indication of an identifier associated withthe UAV 221 and the quantity associated with the charging signal. Inthis fashion, UAV operators can be billed an appropriate amount, forexample.

In some examples, the communications station may interrogate the UAVregarding a remaining battery charge for one or more batteries of theUAV. In some examples, the communications station may interrogate theUAV regarding a fuel level for the UAV. In some examples, thecommunications station may assess, based on the response from the UAV,whether the UAV has sufficient battery power or fuel to reach itsintended destination. In some examples, if the communications stationdetermines that the UAV may not have sufficient battery power or fuel toreach its intended destination, the UAV may suggest (e.g., via atransmitted message) that the UAV charge its batteries (e.g., via thecommunications station as discussed herein with reference to FIG. 4), ormay suggest that the UAV land in a safe landing area (e.g. area 156, seeFIG. 1), where the UAV may refuel or recharge its batteries, or mayobtain other assistance, for example. As another example, thecommunications station may suggest that the UAV land near a locationwhere a mobile communications station is currently located.

In some examples, a communications station may detect a presence of aUAV in a manner other than by establishing communications with the UAV.For example, some implementations of the communications stations caninclude one or more sensors that detect a presence of a UAV. In someexamples, the communications station includes one or more cameras thatcan detect a UAV, as by comparing a captured image of the UAV or of aportion of the UAV (e.g., an identification number or other identifier)with a stored image of a UAV or portion of a UAV. After thecommunications station has detected the presence of the UAV, thecommunications station may interact with the UAV in one or more of theways discussed herein, for example.

In some examples, the communications station includes a firstdirectional microphone that may be directed generally upward (e.g.,toward the sky), and a second directional microphone that may bedirected generally downward (e.g., toward the ground). In some examples,the communications station monitors signals provided by the firstmicrophone and the second microphone, and subtracts the signal of thesecond microphone from the signal of the first microphone. In someexamples, the communications station can use sound isolation or noisecancellation techniques to isolate the background sound to allow thedetection of the UAV. The communications station can compare theresulting signal with a stored signal representation of a UAV, todetermine a presence of the UAV. After the communications station hasdetected the presence of the UAV, the communications station mayinteract with the UAV in one or more of the ways discussed herein, forexample. In some examples, a single microphone is used to detect apresence of a UAV.

In some examples, a communications station 101 detects a UAV (e.g., bycommunicating with the UAV, or as by detection using one or more camerasor microphones) that is unresponsive or uncooperative with thecommunications station 101. The communications station 101 may store, ina memory location of the communications station, an indication of theUAV such as an identifier associated with the UAV, one or more photos orvideos that the communications station captures of the UAV (e.g., usingthe one or more cameras discussed above), or one or more audiorecordings that the communications station captures of the UAV (e.g.,using one or more microphones). In some examples, the communicationsstation may transmit a message with an indication of the unresponsive oruncooperative UAV, for receipt by a police unit, civil airspaceauthority unit, Federal Aviation Administration, or control center orstation remote from the communications station, for example. In someexamples, the message can include an identifier associated with the UAV,one or more photos or videos of the UAV, or one or more audio recordingsassociated with the UAV, as well as an indication of the communicationsstation and/or with an area associated with the communications station(e.g., a location identifier or address).

In some examples, the communications station 101 can detect whether aUAV includes a weapon. For example, the communications station maycapture a photo, image or video of the UAV, and compare with one or morestored photos, images, or videos to determine that the UAV includes aweapon and may be a threat. In some examples, the UAV can transmit amessage with an indication of the UAV determined to include a weapon,for receipt by a police unit, civil airspace authority unit, FederalAviation Administration, or control center or station remote from thecommunications station, for example. In some examples, the message caninclude an identifier associated with the UAV, one or more photos orvideos of the UAV, or one or more audio recordings associated with theUAV, as well as an indication of the communications station and/or withan area associated with the communications station (e.g., a locationidentifier or address).

FIG. 5 is a block diagram 250 of an example communications station 252.In some implementations communications station 252 may correspond to anyof the communications stations (e.g., stations 101, 202, or 222)described herein. Communications station 252 includes a communicationsmodule 254, which includes a communications receiver 256 that canreceive wireless (or in some examples, wired) messages and acommunications transmitter 258 that can transmit wireless (or in someexamples, wired) messages. The communications receiver 256 andcommunications transmitter 258 may receive and transmit messages,respectively, over one or more antennas 260. Communications module 254also includes a security component 262, which can be used to encrypt orencode messages to be sent, and decrypt or decode received messages, andoptionally to provide a security question and answer, to provide forsecure communications between the communications station 252 and a UAV,as will be discussed in further detail below.

A computation unit 264 includes one or more processors that can executeinstructions (e.g., software instructions, firmware instructions, or thelike) and perform functions for the communications station 252. Thecommunications station 252 includes location information 266. Forexample, the location information 266 can include location informationassociated with the communications station 252, or associated with alighting assembly (e.g., a lighting assembly that the communicationsstation 252 is associated with). The location information 266 caninclude, without limitation, location information associated with one ormore roadways or right-of-ways, with one or more right-of-way zones,with one or more air corridors, with one or more obstacles orimpediments, with one or more safe landing zones, with one or moredelivery hub areas, with one or more no-fly zones, or with one or moreother communications stations. Examples of location information caninclude one or more GPS coordinates, one or more of latitude/longitudeinformation or latitude/longitude/elevation information, one or moreInternet Protocol (IP) addresses or other communications-basedaddresses, or the like.

The communications station 252 can include one or more sensors 268. Forexample, the communications station 252 can include one or more sensorsthat can determine wind velocity and/or wind direction. Thecommunications station 252 can include other weather-related sensors(e.g., an ambient light sensor, a precipitation sensor, a thermometer,an air quality sensor, and the like). In some examples, thecommunications station 252 can include one or more altitude-detecting oraltitude-determining sensors that can be used to determine an altitudeat which a UAV is flying, for example. In some examples, thecommunications station 252 can include one or more position-detectingsensors that can be used to determine a position of a UAV, for example.In some examples, the communications station 252 can include one or morevelocity-detecting sensors that can be used to determine a velocity atwhich a UAV is flying, for example. In some examples, the communicationsstation can include one or more cameras or microphones, for example.

The communications station 252 can include a traffic management module270. The traffic management module 270 can be used to manage UAVtraffic, according to some implementations. For example, the trafficmanagement module 270 may determine an appropriate altitude that a UAVshould fly at, and the communications station 252 may communicate anindication of the altitude to the UAV. In some examples, the trafficmanagement module 270 may determine an appropriate air corridor that aUAV should fly in, and the communications station 252 may communicate anindication of the air corridor to the UAV. In some examples, the trafficmanagement module 270 may determine an appropriate altitude range that aUAV should fly within, and the communications station 252 maycommunicate an indication of the altitude range to the UAV. In someexamples, the traffic management module 270 may determine that a UAV isnot flying where it is supposed to be flying, and the communicationsmodule may transmit a message as described herein above. In someexamples, the traffic management module 270 may determine a route for aUAV, or an alternative route based on prevailing traffic conditions,congestion, in-force restrictions (e.g., one or more no-fly zones), orthe like. In some examples, the traffic management module may determinethat that a first UAV is too close to a second UAV (e.g., within apredetermined distance of the second UAV, or vice versa), and thecommunications station 252 may send a warning message to one or both ofthe first UAV and the second UAV.

The communications station 252 includes a data store 272 that can beused to store information, such as information received from one or moreUAVs, or information that the communications station uses in performingthe functions described herein. In some examples, the communicationsstation 252 stores an identifier associated with a UAV in the data store272. In some examples, the communications station 252 stores anidentifier associated with a UAV and a time stamp in the data store 272.In some examples, the communications station 252 stores an identifierassociated with a UAV in the data store 272 after establishingcommunications with the UAV. In some examples, the communicationsstation 252 stores route information associated with a UAV in the datastore 272. In some examples, the communications station 252 storesregistration information (e.g., for particular UAVs or registrationlists) in the data store 272. In some examples, the communicationsstation 252 stores route information associated with a UAV in the datastore 272. In some examples, the communications station 252 storesinformation associated with other communications station in the datastore 272. In some examples, the communications station 252 storesphotos, images, audio files or recordings, and other information in thedata store 272. In some examples, the communications station 252 storesinformation associated with a police department, fire department, civilairspace authority, Federal Aviation Authority, weather service,location service, control center, delivery hub area, mobilecommunications station, or delivery company in the data store 272. Insome examples, the communications station 252 stores informationassociated with a ticket or fine (e.g., a speeding ticket, noise ticket,emissions ticket, no-fly zone ticket, or the like) in the data store 272

The communications station 252 includes a charging unit 274 that mayprovide a charging signal that a UAV can use to charge one or morebatteries of the UAV. A power source 276 provides one or more voltagesto the various electronic components of the communications station 252.Communications station 252 is housed in an enclosure, which may be madeof any appropriate material such as plastic, metal, graphite or othercomposite material, or other appropriate materials. The enclosure canprotect the components of the communications station from the elements,and in some examples from nefarious attempts to gain physical access tothe communications station.

In some examples, the lighting assembly with which the communicationsstation is associated includes a power meter that tracks an amount ofpower used by the communications station (e.g., over a predeterminedperiod of time). In some examples, the power meter may be included withthe communications station (not shown in FIG. 5). In variousimplementations, the power meter may be read or interrogated todetermine the amount of power used. In some examples, the power metertransmits out such information for receipt by a utility company, forexample, or by a control center.

In some examples, a first communications station may communicate withone or more other communications stations. For example, the firstcommunications station may communicate with one or more othercommunications station within a predetermined distance of the firstcommunication station at periodic intervals (e.g., once per minute, pertwo minutes, per five minutes, per ten minutes, per hour, or the like)to confirm that the one or more other communications stations areoperational (e.g., by receiving a response message from the one or moreother communications stations). In the event that one or more of theother communications stations is not operational or is inoperable (e.g.,because of a failure), in some implementations the first communicationsstation may assume communications responsibility for the one or moreinoperable communications stations. For example, the firstcommunications station may initiate communications with UAVs in avicinity of the one or more failed communications stations in the mannerthat the failed communications stations would ordinarily communicatewith the UAVs when operating correctly. In this manner, a redundancy maybe built into the system, for example, which may provide for more robustperformance. The first communications station may store, in one or morememory locations of the first communication station, informationregarding the one or more other communications stations within thepredetermined distance of the first communication station to permit thefirst communications station to assume the communications responsibilityif needed, for example.

FIG. 6 is a flowchart 300 of an example method that can be used tocommunicate with an unmanned aerial vehicle. At a first step 302, afirst message is transmitted for receipt by a UAV, where the firstmessage includes an identifier associated with a lighting assembly. Insome examples, the first message may be transmitted via a communicationstransmitter of a lighting assembly. In some examples, the lightingassembly can be located within a proximity of a roadway. The identifierassociated with the lighting assembly can be an identifier of thelighting assembly or of a communications station associated with thelighting assembly, for example. The identifier can be a locationindicator, such as one or more GPS coordinates, latitude/longitudeinformation, or latitude/longitude/elevation information associated withthe lighting assembly or with a communications station that isassociated with the lighting assembly. In some examples, the firstmessage can include an indication of weather. In some examples, thefirst message can include an indication of speed (e.g., a speed limit).In some examples, the first message can include an indication of a noiselevel or of an emissions level. In some examples, the first message caninclude an indication of one or more safe landing zones, or of one ormore delivery hub areas. In some examples, the first message can includean indication of one or more obstacles or impediments. In some examples,the first message can include an indication of a no-fly zone.

A second message is received, at a second step 304, from the UAV, andthe second message includes an identifier associated with the UAV. Insome examples, the second message can include location informationassociated with the UAV (e.g., one or more GPS coordinates,latitude/longitude information, or latitude/longitude/elevationinformation of the UAV). In some examples, the second message caninclude route information. In some examples, the second message caninclude information descriptive of the UAV, such as the type of UAV, acompany that the UAV is associated with, registration information orlicense information for the UAV, and the like. In some examples, thesecond message can include a request for charging energy that the UAVcan use to charge one or more batteries of the UAV.

At step 306, a third message is transmitted for receipt by the UAV,where the third message includes an indication of an altitude at whichthe UAV should fly. In some examples, the indication of the altitude atwhich the UAV should fly includes an indication of an air corridor,where the air corridor is associated with a predetermined minimumaltitude and a predetermined maximum altitude. In some examples, thethird message includes an indication of an altitude of the UAV (e.g., analtitude that the UAV is currently flying at). In some examples, thethird message includes one or more altitude levels. For example, thethird message may include an altitude range to indicate that the UAVshould fly within the altitude range. In some examples, the thirdmessage includes an indication of direction (e.g., a heading or compassheading). In some examples, the third message includes an indication ofvelocity, such as a velocity that the UAV is currently flying at, or oneor more speed limits (e.g., a maximum speed, a minimum speed, or both).In some examples, the third message includes one or more of the possiblemessage items discussed above with reference to the first message atstep 302.

In some examples, communications between a communications station and aUAV, or between communications stations, or between a communicationsstation and a control center or station or other entities discussedherein, can include a security feature that may be used to help combatagainst nefarious intent by unauthorized parties. For example, inaddition to message encryption on the transmission side and decryptionon the receive side, transmitted messages can include a challengequestion. A receiver of the message could then interpret the challengequestion and provide an answer to the challenge question. If thereceiver provides the correct answer to the challenge question, thereceiver would gain effective access to a payload of the message,whereas if the receiver provides an incorrect answer to the challengequestion, the receiver would not be able to access the payload of themessage.

FIG. 7 illustrates an example of equipment that can be used to implementan example heightened security communications protocol. Asecurity/verification module 302 may create a challenge question and acorresponding answer to the challenge question, and a message payloadmodule 304 may create a payload for the message. A processor 305 mayreceive the challenge question and answer from the security/verificationmodule 302 and may receive the message payload from the message payloadmodule 304, and may arrange them and forward them to anencryption/decryption module 306. In some examples, some or all of thefunctions of the message payload module 304 can be performed by theprocessor 305. In some examples, the processor 305 may correspond tocomputation unit 264 (see FIG. 5). The payload, challenge question andanswer may be encrypted by the encryption/decryption module 306. Thepayload, challenge question and answer may be signed by theencryption/decryption module 306. Thereafter, a transmitter 308 maytransmit the message wirelessly via one or more antennas 310. Wiredtransmission may also be possible in some implementations. In variousexamples, the message may be transmitted over one or more networks, orin one or more manners as discussed above with reference to FIGS. 3A,3B, and 3C.

A message may be wirelessly received via the one or more antennas 310 ata receiver 312. The receiver 312 delivers the encrypted message to theencryption/decryption module 306, where the message is authenticated andthe payload is decrypted. The decrypted payload is then delivered toprocessor 305, which in some examples parses the payload and in someexamples passes the payload to the message payload module 304 forparsing. The processor 305 also delivers the challenge question to thesecurity/verification module 302. The security/verification module 302may interpret the challenge question and reply with an answer to thequestion. The processor 305 can verify that the response from thesecurity/verification module 302 matches the answer included in themessage, and can process the payload if the answer is correct. If theanswer is incorrect, the processor 305 may not be able to process thepayload. This may add an extra layer of security to standardencryption/decryption methods, and may add a specific check on security.In some examples, an entity in charge of the communications stations maybe the only party with access to security/verification module 302. Insome cases, challenge-response security pairs may be one-time-use only,and may be time-limited. The security/verification module 302 may needto provide a correct response within a predetermined period of time;otherwise a timeout may prevent further action.

In some examples, if a security question is incorrectly answered one ormore times (e.g., at a UAV or at a communications station), or after apredetermined number of times, the communications station may notifypolice, civil airspace authorities, the Federal Aviation Administration,the control center, or other appropriate authority. In some examples,some airspaces may be closed down if it is determined that a threatcondition exists. Closing an airspace can also occur when otheremergency or threat conditions described herein occur (e.g., when it isdetermined that a UAV might present a threat or might include a weapon).

In some implementations, all communications between components of thesystem may be subject to a security protocol similar to that describedabove with reference to FIG. 7. For example, communications stations,UAVs, and control centers or stations may include one or more aspects ofFIG. 7 (e.g., encryption/decryption module 306, processor 305,security/verification module 302, message payload module 304,transmitter 308, receiver 312) and may assemble and encode and/or parseand decode messages in the manner described above.

In some cases, encryption and decryption provided by module 306 may besufficient to alleviate security concerns, but in some cases the extrasecurity afforded by the challenge question (or security question) andanswer functionality may be desired. System components that sendmessages may be configured to provide payloads and challengequestions/responses. System components that receive messages may beconfigured to receive and process the payloads and challenge questions.In various implementations, the communications algorithms used by thevarious components may include detection of attempts by unauthorizedparties to jam or hijack the system, as by a type of cyber-attack, ornuisance disturbances designed to trick the system. In some examples, asingle IP address can be used for communication between components ofthe system. In some examples, two IP addresses can be used forcommunication between components of the system. In some implementations,heightened security communications may not be needed, and communicationsmay occur without security questions/answers.

Some or all of the techniques discussed herein can be used to supplementexisting UAV communications protocols, according to variousimplementations. For example, for UAVs that rely primarily on receivedGPS signals to navigate, some or all of the techniques discussed hereinmay provide secondary, supplemental or redundant information or supportto the UAV at times when the UAV is unable to communicate (transmit,receive, or both) in its primary manner. In some implementations, thismay provide a more robust operating environment for UAVs, for example.

FIG. 9 is a block diagram 500 of an example UAV 502. The example UAV 502is depicted in a simplified representation, and may represent any of theUAVs discussed herein, for example. UAV 502 may represent any of varioustypes of UAVs with which the communications stations discussed hereinmay communicate.

UAV 502 includes a communications module 504, which includes acommunications receiver 506 that can receive wireless messages and acommunications transmitter 508 that can transmit wireless messages. Thecommunications receiver 506 and communications transmitter 508 mayreceive and transmit messages, respectively, over one or more antennas509. Communications module 504 also includes a security component 510,which can be used to encrypt or encode messages to be sent, and decryptor decode received messages, and optionally to provide a securityquestion and answer, to provide for secure communications between acommunications station and the UAV 502, as described above. In someexamples, wired communications can be used.

A computation unit 512 includes one or more processors that can executeinstructions (e.g., software instructions, firmware instructions, or thelike) and perform functions for the UAV 502. The UAV 502 includes aflight control module 514 that controls flight operations for the UAV502. In some examples, the flight control module 514 controls operationsrelating to takeoff, landing, and in-flight operations. In someexamples, the flight control module 514 controls navigation operationsfor the UAV 502. In some examples, the flight control module includesnavigational instrumentation. In some examples, the flight controlmodule 514 responds to navigational commands (e.g., from acommunications station such as described herein, from a ground-basedcontrol station or system, from a mobile control station or system, orthe like), and implements them at the UAV 502. The UAV 502 includes oneor more sensors 516 that can be used to aid in aspects of operating theUAV 502. The UAV 502 includes a propulsion unit 518 that can be used forpropelling and providing altitude control and directional control forthe UAV 502.

The UAV 502 includes a data store 520 that can be used to storeinformation for aspects of UAV operation. Examples of information thatcan be stored in the data store 520 can include, without limitation,route information, communications station information, registration orlicense information, communications protocol information, weatherinformation, map-related information, retailer order and deliveryinformation, product information, permission information, and others.

A charging module 522 (which may correspond to the charging module 226of FIG. 4 in some implementations) can be used to charge one or morebatteries 524 of the UAV 502. As described above with reference to FIG.4, the charging module 522 can wirelessly receive a charging signal froma communications station, according to some implementations. In someexamples, the UAV 502 may recharge one or more of its batteries whileairborne, as by receiving a charging signal from a communicationsstation such as depicted in FIG. 4, for example. Wired charging may alsobe used, according to some implementations. In some examples, the one ormore batteries 524 may provide propulsion power to the UAV 502 and oneor more voltages for operating the electronic components of the UAV 502.In some examples, the UAV 502 may be powered by gas or by anotherappropriate fuel, to provide propulsion power.

In some examples, the UAV 502 includes a parachute (not shown in FIG.9), and a parachute deployment module (not shown in FIG. 9). In variousimplementations, the parachute deployment module of the UAV maydetermine that the UAV should deploy its parachute, which may assist theUAV in landing in some implementations. In some examples, the UAV 502may receive a message from a communications station (e.g., station 101a) that instructs the parachute deployment module of the UAV to deploythe parachute of the UAV.

In some examples, the UAV 502 includes an airbag (not shown in FIG. 9),and an airbag deployment module (not shown in FIG. 9). In variousimplementations, the airbag deployment module of the UAV may determinethat the UAV should deploy its airbag, which may partially or completelysurround the UAV and protect the UAV, and which may assist the UAV inlanding in some implementations. For example, the airbag may protect theUAV or limit damage to the UAV in a crash landing, as well aspotentially protecting or minimizing damage or injury to pedestrians,vehicles, or property. In some examples, the UAV 502 may receive amessage from a communications station (e.g., station 101 a) thatinstructs the airbag deployment module of the UAV to deploy the airbagof the UAV. In some examples, the airbag may be deployed in combinationwith a deployment of the parachute, discussed above.

Various communications protocols can be used between the communicationsstations discussed herein and a UAV. In some examples, thecommunications station transmits or emits a beacon message periodically(e.g., once per second, once per couple seconds, once per five seconds,once per 10 seconds, once per 15 seconds, once per 20 seconds, once per25 seconds, once per 30 seconds, once per minute, or the like), and aUAV receives the beacon message and replies by transmitting a messagefor receipt by the communications station. In some examples, the UAVreceives the message, which may include any of the information discussedabove herein with reference to FIG. 1, and does not reply to thecommunications station.

In some examples, the UAV transmits or emits a beacon messageperiodically (e.g., once per second, once per couple seconds, once perfive seconds, once per 10 seconds, once per 15 seconds, once per 20seconds, once per 25 seconds, once per 30 seconds, once per minute, orthe like) and a communications station receives the beacon message andreplies by transmitting a message for receipt by the UAV.

The communications stations described herein, and/or the UAVs describedherein, can include one or more of the following components: processors,memory (e.g., random access memory (RAM) and/or other forms of volatilememory), storage devices (e.g., solid-state hard drive, hard disc drive,and/or other forms of non-volatile memory), high-speed interfacesconnecting various components to each other (e.g., connecting one ormore processors to memory and/or to high-speed expansion ports), and/orlow speed interfaces connecting various components to each other (e.g.,connecting one or more processors to a low speed bus and/or storagedevices). Such components can be interconnected using various busses,and may be mounted across one or more motherboards or circuit boardsthat are communicatively connected to each other, or in otherappropriate manners.

In some implementations, computing devices can include pluralities ofthe components listed above, including a plurality of processors, aplurality of memories, a plurality of types of memories, a plurality ofstorage devices, and/or a plurality of buses. A plurality of computingdevices can be connected to each other and can coordinate at least aportion of their computing resources to perform one or more operations.

Processors can process instructions for execution within computingdevices, including instructions stored in memory and/or on storagedevices. Such processing of instructions can cause various operations tobe performed, such as the operations, tasks, or methods discussedherein. Processors can be implemented as a chipset of chips that includeseparate and/or multiple analog and digital processors. Processors maybe implemented using any of a number of architectures, such as a CISC(Complex Instruction Set Computers) processor architecture, a RISC(Reduced Instruction Set Computer) processor architecture, and/or a MISC(Minimal Instruction Set Computer) processor architecture. Processorsmay provide, for example, coordination of other components computingdevices, such as control of user interfaces, applications that are runby the devices, and wireless communication by the devices.

Memory can store information within computing devices, includinginstructions to be executed by one or more processors. Memory caninclude a volatile memory unit or units, such as synchronous RAM (e.g.,double data rate synchronous dynamic random access memory (DDR SDRAM),DDR2 SDRAM, DDR3 SDRAM, DDR4 SDRAM), asynchronous RAM (e.g., fast pagemode dynamic RAM (FPM DRAM), extended data out DRAM (EDO DRAM)),graphics RAM (e.g., graphics DDR4 (GDDR4), GDDR5). In someimplementations, memory can include a non-volatile memory unit or units(e.g., flash memory). Memory can also be another form ofcomputer-readable medium, such as magnetic and/or optical disks. Storagedevices can be capable of providing mass storage for computing devicesand can include a computer-readable medium, such as a floppy diskdevice, a hard disk device, an optical disk device, a Microdrive, or atape device, a flash memory or other similar solid state memory device,or an array of devices, including devices in a storage area network orother configurations. Computer program products can be tangibly embodiedin an information carrier, such as memory, storage devices, cache memorywithin a processor, and/or other appropriate computer-readable medium.Computer program products may also contain instructions that, whenexecuted by one or more computing devices, perform one or more methodsor techniques, such as those described above.

Computing devices may communicate wirelessly through one or morecommunication interfaces, which may include digital signal processingcircuitry when appropriate. Communication interfaces may provide forcommunications under various modes or protocols, such as GSM voicecalls, messaging protocols (e.g., SMS, EMS, or MMS messaging), CDMA,TDMA, PDC, WCDMA, CDMA2000, GPRS, 4G protocols (e.g., 4G LTE), and/orother appropriate protocols. Such communication may occur, for example,through one or more radio-frequency transceivers. In addition,short-range communication may occur, such as using a Bluetooth, Wi-Fi,or other such transceivers. In addition, a GPS (Global PositioningSystem) receiver module may provide additional navigation- andlocation-related wireless data to computing devices, which may be usedas appropriate by applications running on computing devices.

Computing devices can also include one or more sensors through whichvarious states of and around the computing devices can be detected. Forexample, computing devices can include one or more accelerometers thatcan be used to detect motion of the computing devices and detailsregarding the detected motion (e.g., speed, direction, rotation); one ormore gyroscopes that can be used to detect orientation of the computingdevices in 3D space; light sensors that can be used to detect levels ofambient light at or around the computing devices; touch and presencesensors that can be used to detect contact and/or near-contact with oneor more portions of the computing devices; environmental sensors (e.g.,barometers, photometers, thermometers) that can detect information aboutthe surrounding environment (e.g., ambient air temperature, airpressure, humidity); other motion sensors that can be used to measureacceleration and rotational forces (e.g., gravity sensors, rotationalvector sensors); position sensors that can be used to detect thephysical position of the computing devices (e.g., orientation sensors,magnetometers), and/or other appropriate sensors.

Various implementations of the systems, devices, and techniquesdescribed here can be realized in digital electronic circuitry,integrated circuitry, specially designed ASICs (application specificintegrated circuits), computer hardware, firmware, software, and/orcombinations thereof. These various implementations can includeimplementation in one or more computer programs that are executableand/or interpretable on a programmable system including at least oneprogrammable processor, which may be special or general purpose, coupledto receive data and instructions from, and to transmit data andinstructions to, a storage system, at least one input device, and atleast one output device. These computer programs (also known asprograms, software, software applications, or code) can include machineinstructions for a programmable processor, and can be implemented in ahigh-level procedural and/or object-oriented programming language,and/or in assembly/machine language. As used herein, the terms“machine-readable medium” “computer-readable medium” refers to anycomputer program product, apparatus and/or device (e.g., magnetic discs,optical disks, memory, Programmable Logic Devices (PLDs)) used toprovide machine instructions and/or data to a programmable processor.

In some implementations, UAVs may fly directly from point-to-point(e.g., directly from a warehouse to a residence) without regard forright-of-ways or right-of-way zones, or with only partial regard forright-of-ways or right-of-way zones, and in such implementations thecommunications stations discussed herein may communicate with the UAVsin similar manners as discussed herein above, including providing any ofthe information discussed herein above to the UAV or receiving any ofthe information discussed herein above from the UAV, without limitation.

The above description provides examples of some implementations. Otherimplementations that are not explicitly described above are alsopossible, such as implementations based on modifications and/orvariations of the features described above. For example, the techniquesdescribed above may be implemented in different orders, with theinclusion of one or more additional steps, and/or with the exclusion ofone or more of the identified steps. Additionally, the steps andtechniques described above as being performed by some computing devicesand/or systems may alternatively, or additionally, be performed by othercomputing devices and/or systems that are described above or othercomputing devices and/or systems that are not explicitly described.Similarly, the systems, devices, and apparatuses may include one or moreadditional features, may exclude one or more of the identified features,and/or include the identified features combined in a different way thanpresented above. Features that are described as singular may beimplemented as a plurality of such features. Likewise, features that aredescribed as a plurality may be implemented as singular instances ofsuch features. The drawings are intended to be illustrative and may notprecisely depict some implementations. Variations in sizing, placement,shapes, angles, and/or the positioning of features relative to eachother are possible.

The above description is intended to be illustrative, withoutlimitation. A number of implementations and examples have beendescribed. Nevertheless, it will be understood that variousmodifications may be made. Accordingly, other implementations are withinthe scope of the following claims.

What is claimed is:
 1. A computer-implemented method of communicatingwith an unmanned aerial vehicle, comprising: transmitting a firstmessage, via a communications transmitter of a lighting assembly forreceipt by an unmanned aerial vehicle, the first message comprising anidentifier associated with the lighting assembly, wherein the lightingassembly is located within a proximity of a roadway; receiving a secondmessage from the unmanned aerial vehicle via a communications receiverof the lighting assembly, the second message comprising an identifierassociated with the unmanned aerial vehicle; and transmitting a thirdmessage via the communications transmitter of the lighting assembly forreceipt by the unmanned aerial vehicle, the third message comprising anindication of an altitude at which the unmanned aerial vehicle shouldfly.
 2. The computer-implemented method of claim 1, wherein theindication of the altitude at which the unmanned aerial vehicle shouldfly comprises an identifier of an air corridor having associatedtherewith a predetermined minimum altitude and a predetermined maximumaltitude.
 3. The computer-implemented method of claim 1, furthercomprising determining, via a computation unit of the lighting assembly,an altitude of the unmanned aerial vehicle, and wherein the thirdmessage includes the altitude of the unmanned aerial vehicle.
 4. Thecomputer-implemented method of claim 3, wherein the identifierassociated with the unmanned aerial vehicle includes a locationindicator of the unmanned aerial vehicle, and wherein determining thealtitude of the unmanned aerial vehicle is based on the locationindicator of the unmanned aerial vehicle and on a location identifier ofthe lighting assembly.
 5. The computer-implemented method of claim 1,wherein the identifier associated with the lighting assembly includes alocation identifier of the lighting assembly.
 6. Thecomputer-implemented method of claim 5, wherein the location identifierof the lighting assembly includes one or more GPS coordinates associatedwith the lighting assembly.
 7. The computer-implemented method of claim1, wherein the roadway is associated with a right-of-way, and whereinthe identifier associated with the lighting assembly includes a locationindicator associated with the right-of-way.
 8. The computer-implementedmethod of claim 7, wherein the identifier associated with the unmannedaerial vehicle includes a location indicator of the unmanned aerialvehicle, further comprising determining that the unmanned aerial vehicleis outside of an airspace associated with the right-of-way, and whereinthe third message includes a warning that the unmanned aerial vehicle isoutside of the airspace associated with the right-of-way.
 9. Thecomputer-implemented method of claim 1, wherein the first messagefurther comprises an indication of a landing area.
 10. Thecomputer-implemented method of claim 1, wherein the first messagefurther comprises a location identifier associated with an obstacle. 11.The computer-implemented method of claim 1, further comprising storingin a memory location of the lighting assembly the identifier associatedwith the unmanned aerial vehicle and a time stamp.
 12. Thecomputer-implemented method of claim 11, further comprising transmittinga fourth message via the communications transmitter of the lightingassembly for receipt by a control center remote from the lightingassembly, the fourth message including the identifier associated withthe unmanned aerial vehicle and the time stamp.
 13. Thecomputer-implemented method of claim 1, further comprising transmitting,from a charging unit of the lighting assembly, a wireless chargingsignal for receipt by the unmanned aerial vehicle for charging a batteryof the unmanned aerial vehicle.
 14. The computer-implemented method ofclaim 13 further comprising transmitting a fourth message via thecommunications transmitter of the lighting assembly, the fourth messagecomprising the identifier associated with the unmanned aerial vehicleand a quantity associated with the wireless charging signal.
 15. Thecomputer-implemented method of claim 1, wherein each of the firstmessage, the second message, and the third message is encrypted forsecurity.
 16. The computer-implemented method of claim 15, wherein eachof the first message the second message, and the third message includesa security question.
 17. The computer-implemented method of claim 1,wherein the identifier associated with the unmanned aerial vehicleincludes a location indicator of the unmanned aerial vehicle, andfurther comprising: determining that the unmanned aerial vehicle iswithin a predetermined distance of a second unmanned aerial vehiclebased on the location indicator of the unmanned aerial vehicle and oninformation received from the second unmanned aerial vehicle; whereinthe third message further comprises a warning that the unmanned aerialvehicle is within the predetermined distance of the second unmannedaerial vehicle.
 18. The computer-implemented method of claim 17, furthercomprising determining a navigational adjustment for the unmanned aerialvehicle, and wherein the third message further comprises thenavigational adjustment for the unmanned aerial vehicle.
 19. Thecomputer-implemented method of claim 1, wherein the first messagefurther includes an indication of weather.
 20. The computer-implementedmethod of claim 1, wherein the first message further includes anindication of a speed.
 21. The computer-implemented method of claim 1,further comprising determining a speed of the unmanned aerial vehicle.22. The computer-implemented method of claim 21, wherein the speed ofthe unmanned aerial vehicle exceeds a predetermined speed threshold, andfurther comprising transmitting a fourth message that includes anindication of the speed of the unmanned aerial vehicle.
 23. Thecomputer-implemented method of claim 1, wherein the first messagefurther includes an indication of a noise level.
 24. Thecomputer-implemented method of claim 1, wherein the first messagefurther includes an indication of an emissions level.
 25. Thecomputer-implemented method of claim 1, wherein the identifierassociated with the unmanned aerial vehicle includes license orregistration information for the unmanned aerial vehicle, and furthercomprising determining whether the license or registration informationfor the unmanned aerial vehicle is valid.
 26. The computer-implementedmethod of claim 1, further comprising determining that the unmannedaerial vehicle includes a weapon.
 27. The computer-implemented method ofclaim 1, wherein the first message includes an indication of an areathat the unmanned aerial vehicle should avoid.
 28. A lighting assembly,comprising: a light pole located within a proximity of a roadway; aluminaire; and a communications station associated with the lightingassembly, the communications station comprising: a communicationstransmitter configured to transmit a first message for receipt by anunmanned aerial vehicle, the first message comprising an identifierassociated with the lighting assembly; a communications receiverconfigured to receive a second message from the unmanned aerial vehicle,second message comprising an identifier associated with the unmannedaerial vehicle; and a processing module configured to determine analtitude at which the unmanned aerial vehicle should fly; wherein thecommunications transmitter is further configured to transmit a thirdmessage for receipt by the unmanned aerial vehicle, the third messagecomprising an indication of the altitude at which the unmanned aerialvehicle should fly.
 29. The lighting assembly of claim 28, wherein theindication of the altitude at which the unmanned aerial vehicle shouldfly comprises an identifier of an air corridor having associatedtherewith a predetermined minimum altitude and a predetermined maximumaltitude.
 30. The lighting assembly of claim 28, wherein the processingmodule is further configured to determine an altitude of the unmannedaerial vehicle, and wherein the third message includes the altitude ofthe unmanned aerial vehicle.